KR20130136869A - Measurement apparatus of gap and measuring method of roll gap using the same - Google Patents

Abstract

The present invention relates to an apparatus for measuring a gap between upper and lower rolls. The invention comprises upper and lower rising blocks which are separately installed above and below and which move up and down; a gap measuring unit having a slide block which moves the upper and lower rising blocks up and down by horizontally moving between the upper and lower rising blocks; and a control module which measures an actual gap between the upper and lower rising blocks using a distance the slide block horizontally moves and a change in the distanced between the upper and lower rising blocks. So, the invention accurately measures and controls the gap between the upper and lower rolls relatively to the existing invention. Also, the invention is easily controlled and maintained by monitoring the gap between the upper and lower rolls in real time. [Reference numerals] (410) Adjusting unit;(420) Comparing unit;(430) Calculation unit;(440) Display unit

Description

Gap measuring apparatus and gap measuring method using same {Measurement apparatus of gap and measuring method of roll gap using the same}

The present invention relates to a gap measuring apparatus and a gap measuring method using the same, and more particularly, to a gap measuring apparatus and a gap measuring method using the same, which can easily measure the gap between the upper and lower rolls.

A typical player is a ladle containing molten steel, a tundish for temporarily storing the molten steel through an injection nozzle connected to the ladle, a mold for initial solidifying the molten steel received from the tundish into a constant shape, and the bottom side of the mold to be arranged in one direction. And a plurality of segments arranged to perform a series of operations to bend or straighten while cooling unsolidified slabs.

The segment includes a plurality of upper rolls arranged in one direction and a plurality of lower rolls spaced below the plurality of upper rolls and arranged in a direction corresponding to the plurality of upper rolls. The unsolidified cast piece is cooled while passing between the plurality of upper and lower rolls.

On the other hand, in order to produce a cast of the desired quality, the gap between the upper roll and the lower roll should be maintained at a constant gap. However, if the process proceeds continuously or an error occurs in the segment, the gap between the upper roll and the lower roll may change. Thus, the gap between the upper and lower rolls was measured, and the gap between the upper and lower rolls was adjusted according to the measured value.

However, in the related art, the operator directly measures the gap between the upper roll and the lower roll using a micrometer. That is, the operator inserts the micrometer between the upper roll and the lower roll, and measures the gap using the micrometer. However, since the operator measures the gap manually, the measurement takes a long time, there is a problem that an error occurs depending on the operator. In addition, since the operator's hand enters between the rolls during the measurement work, there is a risk of a safety accident.

Korean Utility Model No. 20-1998-0022072 discloses an apparatus for measuring roll spacing using an electric micrometer.

Korean Practical Use No. 20-1998-0022072

One technical problem of the present invention is to provide a gap measuring device that can easily measure the gap between the upper roll and the lower roll and a gap measuring method using the same.

Another technical problem of the present invention is to provide a gap measuring device capable of safely measuring a gap between an upper roll and a lower roll, and a gap measuring method using the same.

The present invention is a gap measuring device for measuring the gap between the upper roll and the lower roll, disposed in the vertical direction spaced apart, the lower lifting block and the lower lifting block; And a slide block positioned on one side of the upper elevating block and the lower elevating block to move horizontally between the upper elevating block and the lower elevating block to elevate the upper elevating block and the lower elevating block. A gap measuring unit having a; And a control module for calculating an actual gap between the upper roll and the lower roll using a change in the separation distance between the upper lifting block and the lower lifting block and a horizontal moving distance of the slide block.

The slide block has an upper inclined surface connected with the upper elevating block and a lower inclined surface connected with the lower elevating block, the upper inclined surface is inclined downward toward the upper elevating block, and the lower inclined surface is in the lower elevating block therebetween. It is a shape inclined upwardly.

The upper elevating block may include an upper rotating member which rotates and descends along an upper inclined surface of the slide block; An upper elevating block connected to an upper portion of the upper rotating member; An upper tip connected to the upper elevating block, wherein the lower elevating block comprises: a lower rotating member rotating along the lower inclined surface of the slide block; A lower elevating block connected to a lower portion of the lower rotating member; It includes a lower tip connected to the lower lifting block.

When the slide block moves horizontally in the direction in which the upper lifting block and the lower lifting block are located, the upper rotating member rises along the upper inclined surface of the slide block, and the lower rotating member moves the lower inclined surface of the slide block. When the slide block is moved horizontally in the opposite direction to the upper lifting block and the lower lifting block, the upper rotating member is lowered along the upper inclined surface of the slide block, the lower rotating member is the slide block Rises along the bottom slope.

The upper tip and the lower tip are arranged to be orthogonal to the slide block.

A driving unit provided extending from the other side of the upper elevating block and the lower elevating block, at least one end of which is fastened to the slide block through a space between the upper rotating member and the lower rotating member and is provided with a driving member that moves horizontally; Include.

It is connected to the drive member, and includes a stretchable elastic member.

It is connected to the drive unit, and includes an operation unit for rotating the drive unit.

The control module may include a calculation unit configured to calculate a gap between the upper roll and the lower roll using a change in the separation distance between the upper tip and the lower tip and a horizontal movement distance of the slide block; A comparison unit comparing the operation value calculated by the operation unit with a reference value; And an adjusting unit for raising and lowering at least one of the upper roll and the lower roll according to the result of comparison in the comparing unit.

The gap measuring unit is provided in plural, and is spaced apart from each other between the upper roll and the lower roll, and measures the gap between the upper roll and the lower roll at each position.

A slide for vertically moving the upper and lower lifting blocks and the lower raising and lowering blocks and horizontally moving between the upper and lower lifting blocks and the lower raising and lowering blocks to raise and lower the upper and lower lifting blocks. A gap measuring method using a gap measuring device including a gap measuring unit having a block and a control module interlocked with the gap measuring unit and measuring an actual gap between an upper roll and a lower roll, the gap measuring unit includes an upper roll; Located between the lower roll, and calculating the actual gap between the upper roll and the lower roll using the change in the separation distance between the upper lifting block and the lower lifting block and the horizontal movement distance of the slide block. .

And setting a zero point of the upper and lower lifting blocks of the gap measuring unit.

A plurality of gap measuring units are provided, and the plurality of gap measuring units are arranged to be spaced apart from each other between the upper roll and the lower roll, and the gap is measured at a plurality of points.

According to embodiments of the present invention, the gap between the upper roll and the lower roll can be measured and controlled more accurately than in the related art. In addition, the gap measurement between the upper roll and the lower roll and accordingly the gap adjustment is made automatically, because it is monitored in real time, there is an advantage that it is easy to repair or control.

In addition, since the operator does not directly measure between the upper roll and the lower roll as in the prior art, the measurement is performed automatically, thereby preventing the risk of an accident.

1 and 2 illustrate a gap measuring device according to an embodiment of the present invention.
3 is a view showing a setting device according to an embodiment of the present invention;
4 shows an appearance of a gap measuring unit according to an embodiment of the present invention.
5 is a cross-sectional view showing main parts of a gap measuring unit;
6A and 6B are cross-sectional views illustrating the operation of a measuring device according to an embodiment of the present invention.
7A to 7E and 8A and 8B are views sequentially showing an operation of measuring a gap between an upper roll and a lower roll of a segment using a gap measuring device according to an embodiment of the present invention.
9A and 9B are cross-sectional views for explaining the operation of the gap measuring unit in measuring the gap between the upper and lower rolls by placing the gap measuring unit between the upper and lower rolls.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various forms, and only the embodiments are intended to complete the disclosure of the present invention and to those skilled in the art. It is provided for complete information.

1 and 2 illustrate a gap measuring apparatus according to an embodiment of the present invention. 1 is a view showing a state where the setting device and the gap measuring unit is separated, and FIG. 2 is a view showing a state in which the gap measuring unit is seated on the setting device for setting of the gap measuring unit. 3 is a view showing a setting device according to an embodiment of the present invention. 4 is a diagram illustrating an appearance of a gap measuring unit according to an exemplary embodiment of the present invention. 5 is a cross-sectional view showing the main portion inside the gap measuring unit.

1 and 2, a gap measuring apparatus according to an embodiment of the present invention includes a plurality of gap measuring units 300 and a gap measuring unit measuring gaps between a lower roll and an upper roll of a segment. The setting device 200 for setting the 'O (Zero)' point of the 300, receiving the data measured by the plurality of gap measuring units 300 detects the gap between the upper roll and the lower roll in real time, and The control module 400 for controlling the gap between the upper roll and the lower roll, the plurality of gap measuring units 300 and the setter 200 are seated and include a movable moving cart 100.

The moving trolley 100 is for moving the plurality of gap measuring units and the setter 200 to a place for measuring a gap, that is, a workplace, and may have a structure in which a wheel for moving is installed at a lower end thereof. . In addition, the moving cart 100 has an accommodation space in which the plurality of gap measuring units 300 are accommodated, and the setting device 200 is mounted on the moving cart 100. Of course, the present invention is not limited thereto, and the gap measurement unit 300 and the setter 200 may be changed into various shapes and structures that may be seated and moved.

The setting device 200 is for aligning the 'zero' point of the gap measuring unit 300, and as shown in FIG. 3, the seating member 210 on which the gap measuring unit 300 is mounted, extends in a vertical direction. Fixed member 220 installed at one end thereof so as to be coupled to the seating member 210, and extended in a horizontal direction, so that one end is coupled to the fixed member 220 and is positioned above the seating member 210. And a micrometer extending in the vertical direction and having one end penetrating the support member 250, the display member 270 displaying the value measured by the micrometer 230, and the support member 250. A lever 260 that raises or lowers the support member.

Since the micrometer 230 uses a general micrometer, a detailed description thereof will be omitted.

As described above, the seating member 210 is a means for seating the gap measuring unit 300 at the time of setting the zero point of the gap measuring unit, and has a larger area than the gap measuring unit 300. It is preferable to be manufactured to have. The seating member 210 according to the embodiment may be manufactured in a plate shape having a rectangular cross-sectional shape, but is not limited thereto and may be manufactured in various shapes in which the gap measuring unit 300 may be seated.

The fixing member 220 is for supporting and fixing the supporting member 250. In the embodiment, the fixing member 220 is manufactured to have a cylindrical shape and installed to be perpendicular to the seating member 210. The support member 250 is coupled to the fixing member 220, and the support member 250 has a bar shape extending in a direction parallel to the upper surface of the seating member. Both ends of the support member 250 are provided with through holes, and the fixing member 220 is inserted into the through hole provided at one end, and the micrometer 230 is inserted into the through hole provided at the other end. At this time, the lower end of the micrometer 230 is installed to be exposed to the lower portion of the support member 250 or to a predetermined length.

The gap measuring unit 300 measures a gap between the upper roll and the lower roll of the segment, and is provided in plurality. In the embodiment, the plurality of gap measuring units 300 are disposed to be spaced apart from each other in a space between a plurality of upper rolls arranged in one direction and a plurality of lower rolls arranged in one direction. Thus, the gap between the upper roll and the lower roll is measured at a plurality of points. In the exemplary embodiment, four gap measuring units 300 are provided, but the present invention is not limited thereto, and a plurality of gap measuring units 300 may be provided.

4 and 5, each of the plurality of gap measuring units 300 may be disposed in the housing 310, a cover 341 installed inside the housing 310, and an upper portion spaced apart in the vertical direction in the cover 341. A slide block 345 and a slide block 345 which are horizontally movable by being disposed corresponding to the space between the elevating block 342a and the lower elevating block 342b, the upper elevating block 342a and the lower elevating block 344b. A horizontal moving unit 346 for horizontally moving a), one end is mounted to be inserted into the cover 341, the driving unit 347 connected to one end of the slide block 345, the upper elevating block 342a and the lower elevating block And a measuring unit 349 for detecting a change in the separation distance or the change in the position of 342b. In addition, an indicator that displays a measurement value, that is, a gap that is calculated and derived from the control module 400 by being mounted on the operation unit 348 connected to the driving unit 347 protruding out of the housing 310 and the outer circumferential surface of the housing 310. 330, a button mounted on the housing 310 and interlocked with the control module 400 and the measurement unit 349 to set a zero of the gap measurement unit 300.

Referring to FIG. 4, the housing 310 has a cylindrical shape having an internal space, and a groove 311-4 having a predetermined area is provided below. The groove 311-4 is positioned between the upper roll and the lower roll of the gap measuring unit 300 so that the lower roll is inserted into the groove 311-4 of the housing 310 when it is seated on the lower roll. This is to allow the lower end of the lower tip 342b-3 positioned in the housing 310 to easily contact the lower roll. In the embodiment, the groove 311-4 is manufactured in a shape in which the width thereof becomes narrower from the lower end of the housing 310 toward the upper direction. However, the groove 311-4 is not limited thereto, and the lower roll can be easily moved downward of the groove 311-4. It can be manufactured in various shapes that can be inserted. In addition, the housing 310 is provided with an upper opening 311-1 and a lower opening 311-2, and the upper opening 311-1 has an upper tip 342a-3 and an upper elevating member 342a which will be described later. -2) is a space in which the upper portion protrudes or is exposed, and the lower opening 311-2 and the lower lifting member 342b-2 are spaces in which the lower portion of the housing 310 protrudes or is exposed. The lower opening 311-2 is located above the groove 311-4 described above.

Referring to FIG. 5, the upper elevating block 342a is located in the cover 341 and rotates along the upper surface of the slide block 345 to elevate and rotate the upper rotating member 342a-1 and the upper rotating member 342a. It includes an upper elevating member (342a-2) connected to the upper portion of -1), an upper tip (342a-3) connected to the upper elevating member (342a-2). In addition, the lower lifting block 342b rotates along the lower surface of the slide block 345 to lower and lower the lower rotating member 342b-1 and the lower lifting member connected to the lower portion of the lower rotating member 342b-1 ( 342b-2) and a lower tip 342b-3 connected to the lower elevating member 342b-2.

Cover 341 is installed in the housing 310, the upper end is provided with an upper opening (341-1) protruding by the upper tip (342a-3) is raised, the lower tip (342b-3) is lowered A protruding lower opening 341-2 is provided. Here, the upper opening 341-1 provided in the cover 341 communicates with the upper opening 311-1 provided in the housing 310, and the lower opening 341-2 provided in the cover 341 is the housing 310. It communicates with the lower opening 311-2 provided in the.

The upper tip 342a-3 and the lower tip 342b-3 are installed to be spaced up and down on a vertical line in the cover 341, and are raised or lowered by the slide block 345 or the driving unit 347, which will be described later. And it protrudes to the outside of the upper openings 311-1 and 341-1 and the lower openings 311-2 and 341-2 provided in each of the cover 341 and the housing 310 by the raising or lowering operation, Will be located.

The upper elevating member 342a-2 is positioned between the upper tip 342a-3 and the upper rotating member 342a-1 to support the upper tip 342a-3 and the upper rotating member 342a-1. It is possible to move up and down by the operation of the upper rotating member (342a-1). In addition, the lower elevating member 342b-2 is positioned between the lower tip 342b-3 and the lower rotating member 342b-1, and the lower tip 342b-3 and the lower rotating member 342b-1. It is supported by, the lifting and lowering is possible by the operation of the lower rotating member (342b-1).

The upper rotating member 342a-1 and the lower rotating member 342b-1 may be, for example, ball bearings by means of rotatable means. Here, a part of the upper rotating member 342a-1 is connected to the lower part of the upper elevating member 342a-2, and the other part is installed to contact the upper surface 345-2a of the slide block 345 described later. In addition, a part of the lower rotating member 342b-1 is connected to the upper part of the lower elevating member 342b-2, and the other part is installed to contact the lower surface 345-2b of the slide block 345. A detailed description of the movement of the upper elevating member 342a-2 and the lower elevating member 342b-2 by the rotation of the upper rotating member 342a-1 and the lower rotating member 342b-1 will be given below. Shall be.

The slide block 345 is formed to extend in a horizontal direction and is mounted to move horizontally in a direction orthogonal to the upper and lower tips 342a-3 and 342b-3 moving up and down. Here, the slide block 345 is preferably installed so that each of the upper tip 342a-3 and the lower tip 342b-3 and the arrangement structure becomes a triangle. In other words, the angle formed by the horizontal extension line at the center of the slide block 345 and the vertical extension line of the upper tip is 90 °, and is arranged to form a right triangle. Similarly, the angle formed by the horizontal extension line at the center of the slide block 345 and the vertical extension line of the lower tip 342b-3 is 90 °, and is arranged to form a right triangle. The slide block 345 according to the embodiment is manufactured in a shape such that an arrow (<-) shape becomes narrower in the direction in which the upper and lower rotating members 342a-1 and 342b-1 are located. That is, the slide block 345 has a body 345-1 extending in the horizontal direction, one end is connected to the body 345-1, the other end is inserted into the cover 341, the upper rotating member 342a-1 and the lower And an insertion member 345-2 positioned corresponding to an area between the rotation members 342b-1 and insertable between the upper and lower rotational members 342a-1 and 342b-1. Here, the insertion member 345-2 has a shape in which the width thereof becomes narrower toward the direction in which the upper and lower rotary members 342a-1 and 342b-1 are positioned in the direction in which the body 345-1 is located, for example, the cross section is triangular. It is manufactured in the shape of phosphorus. Thus, as shown in the enlarged view of the slide block 345 shown in Figure 5, the upper surface (345-2a) of the insertion member 345-2 is inclined upward in the direction in which the body 345-1 is located, the lower surface ( 345-2b) is inclined downward in the direction in which the body 345-1 is located. Hereinafter, for convenience of description, the upper surface 345-2a of the insertion member 345-2 is referred to as the upper inclined surface 345-2a, and the lower surface 345-2b is referred to as the lower inclined surface 345-2b. Name it. At this time, the inclination angle of the insertion member 345-2, the upper inclined surface 345-2a and the lower inclined surface 345-2b is preferably 45 degrees. That is, the angle θ ₁ and the body 345-formed by a body extension line extending horizontally from the center of the body 345-1 and an upper extension line extending along the upper inclined surface 345-2a of the insertion member 345-2. 1) it is preferable that the extension and the insert member (345-2) and a lower inclined surface (345-2b), the lower extension is the angle θ ₂ is 45 ° extending along. In this way, the slide block 345 is installed to be in a direction orthogonal to the upper tip 342a-3 and the lower tip 342b-3, and each of the upper inclined surface 345-2a and the lower inclined surface 345-2b The manufacturing angle of the upper tip 342a-3 and the lower tip 342b-3 is 45 ° so that the distance between the upper tip 342a-3 and the lower tip 342b-3 and the slide block 345 are increased. This is to calculate roll gap by applying horizontal movement distance of) to trigonometric function.

In addition, a screw groove 345-3 for fastening with the driving unit 347 to be described later is provided in the insertion member 345-2 of the slide block 345.

The horizontal moving part 346 is connected to the slide block 345 to horizontally move the slide block 345. In an embodiment, the horizontal moving part 346 may be a means consisting of an LM guide, a linear motor, a linear encoder, and a linear scale. Here, the linear encoder detects the horizontal moving distance of the slide block 345 and transmits the horizontal moving distance of the slide block 345 to the control module.

In the above description, a combination of the LM guide, the linear motor, the linear encoder, and the linear scale is described as the horizontal moving unit 346. However, the present invention is not limited thereto, and various means for horizontally moving the slide block 345 may be used.

The driving unit 347 is positioned between the upper rotating member 342a-1 and the lower rotating member 342b-1, one end of which is a driving member 347-3 connected to the slide block 345, and one end of the driving member 347. -3) and the other end is inserted into the connecting member 347-2 and the connecting member 347-2 connected to the operation unit 348 so that one end is connected to the driving member 347-3 and the other end is connected to the connecting member347-. And an elastic member 347-1 connected with 2).

The driving member 347-3 extends in the horizontal direction between the upper rotating member 342a-1 and the lower rotating member 342b-1, and the upper rotating member 342a-1 and the lower rotating member 342b-1. It is arranged to cross the space between. In addition, a screw thread 347-4 is formed on an outer circumferential surface of the driving member 347-3, and a screw groove having one end on which the thread 347-4 is formed is provided in the insertion member 345-2 of the slide block 345. Is fastened to 345-3.

The connection member 347-2 is disposed to connect the operation unit 348 and the driving member 347-3, and an elastic member 347-1 is provided therein. The elastic member 347-1 provides an elastic force to the driving member 347-3 and may be a spring.

As such, in the gap measuring unit according to the embodiment of the present invention, the upper and lower lifting blocks 342a and 342b are rotated and lowered along the upper and lower inclined surfaces 345-2a and 345-2b of the slide unit 345. The driving member 347-3, which horizontally moves the slide unit 345, is connected to the elastic member 347-1 having an elastic force. Thus, each of the upper elevating block 342a and the lower elevating block 342b has an elastic force. That is, when the upper elevating block 342a and the lower elevating block 342b are pressed, the upper elevating block 342a and the lower elevating block 342b are close to each other. The inclined surfaces 345-2a and 345-2b and the elastic member 347-1 have elastic force to return to the original position. Therefore, for example, when the upper elevating block 342a is pressed by the upper roll, and the lower elevating block 342b is pressed by the lower roll, the upper elevating block 342a and the lower elevating block 342b. It moves closer together, and when pressurization is released, it returns to an original state by elastic force. Further, when each of the upper elevating block 342a and the lower elevating block 342b is kept unpressurized, the upper elevating block 342a is maximized and the lower elevating block 342b is maximum. May be lowered.

The measuring unit 349 locates the gap measuring unit 300 between the upper roll and the lower roll, and when measuring the separation distance between the upper roll and the lower roll, the upper tip 342a-3 and the lower tip 342b. -3) Measure the separation distance and change of separation distance. That is, based on a preset '0 (zero)' at the time of measuring the actual gap, the change in the moving distance or the separation distance of each of the upper tip 342a-3 and the lower tip 342b-3 is measured. The moving distance or the separation distance of each of the upper tip 342a-3 and the lower tip 342b-3 measured by the measuring unit 349 is transmitted to the control module 400.

6A and 6B are cross-sectional views illustrating the operation of the measuring unit according to the embodiment of the present invention. 5, 6a and 6b, the operation of the measuring unit according to the embodiment of the present invention will be described.

As shown in FIG. 6A, when the operator rotates the operation unit 348 counterclockwise, for example, the driving member 347-3 of the driving unit 347 rotates counterclockwise, and the driving member 347-3 ) Moves in the direction in which the operation unit 348 is located. In other words, the driving member 347-3 moves in the opposite direction from the upper elevating block 342a and the lower elevating block 342. In this case, since the elastic member 347-1 is connected to the other end of the driving member 347-3, the driving member 347-3 moves in the direction in which the operation unit 348 is located, and thus, the elastic member 347-1. ) Contracts. In addition, since the drive member 347-3 is engaged with the insertion member 345-2 of the slide block 345, the thread 347-4 of the drive member 347-3 is inserted into the insertion member 345-2. The slide block 345 is also horizontally moved in the direction in which the operation unit 348 is located while being fastened to the screw groove 345-3. At this time, since the insertion member 345-2 of the slide block 345 moves while being inserted into the space between the upper rotating member 342a-1 and the lower rotating member 342b-1, the upper rotating member 342a-1 is moved. It rotates along the upper inclined surface 345-2a of the insertion member 345-2, and the lower rotating member 342b-1 rotates along the lower inclined surface 345-2b of the insertion member 345-2. Accordingly, the upper rotating member 342a-1 is raised while rotating along the upper inclined surface 345-2a of the inserting member 345-2, and the lower rotating member 342b-1 is inserted into the inserting member 345-2. It descends while rotating along the lower inclined surface 345-2b. Accordingly, the upper elevating member 342a-2 and the upper tip 342a-3, which are coupled to the upper rotating member 342a-1, are raised, and the lower elevating member (coupled to the lower rotating member 342b-1). 342b-2) and the lower tip 342b-3 are lowered.

In addition, as shown in FIG. 6B, for example, when the operator rotates the operation unit 348 in the clockwise direction, the driving member 347-3 rotates in the clockwise direction, and the driving member 347-3 is operated by the operation unit 348. Move in a direction opposite to that of the slide block 345. Thus, the elastic member 347-1 connected to the driving member 347-3 is extended as compared with the case of FIG. 6A. Then, the slide block 345 engaged with the driving member 347-3 horizontally moves in the direction opposite to the operation unit 348. Therefore, the upper rotating member 342a-1 is lowered while rotating along the upper surface of the inserting member 345-2 horizontally moving in the direction opposite to the operation unit 348, and the lower rotating member 342b-1 is inserted into the insert. Ascending while rotating along the lower surface of the member 345-2. Accordingly, the upper elevating member 342a-2 and the upper tip 342a-3, which are coupled to the upper rotating member 342a-1, are lowered, and the lower elevating member coupled to the lower rotating member 342b-1 ( 342b-2) and the lower tip 342b-3 rise.

In the above, the upper tip 342a-3 rises at the counterclockwise rotation of the operation portion 348, the lower tip 342b-3 descends, and the upper tip 342a- at the clockwise rotation of the operation portion 348. It has been described that 3) descends and the lower tip 342b-3 rises. However, the present invention is not limited thereto and may be reversed depending on the shape of the driving member 347-4 provided in the driving member 347-3 and the screw groove 345-3 provided in the insertion member 345-2.

The control module 400 is connected to the plurality of gap measuring units 300 and the segment, and calculates the gap between the upper and lower rolls of the segment using data measured by the plurality of gap measuring units 300. The gap between the upper and lower rolls is adjusted according to the calculated value. The control module 400 receives the data measured by each of the plurality of gap measuring units 300 and calculates a plurality of calculation values calculated by the operation unit 430 and the operation unit 430 to calculate the gap between the upper and lower rolls. The display unit 440 for displaying a, a comparison unit 420 for comparing the preset reference value and the operation value, and the adjusting unit 410 for instructing the operation of the segment according to the comparison result in the comparison unit 420.

The calculation unit 430 according to the embodiment uses the gap between the upper tip 342a-3 and the lower tip 342b-3 of the gap measuring unit 300 and the horizontal movement distance of the slide block 345 to form an upper roll. Calculate the separation distance between and the lower roll. At this time, the upper tip 342a-3 and the lower tip 342b-3 and the slide block 345 are spaced apart from each other to form a triangle, the insertion member 345-2 of the slide block 345 Since the upper inclined surface 345-2a and the lower inclined surface 345-2b are 45 °, in the embodiment, the separation distance between the upper roll and the lower roll is calculated by a calculation using a trigonometric function.

On the other hand, the segments are arranged spaced apart from the plurality of upper rolls, the plurality of upper rolls arranged in one direction, the plurality of lower rolls and the plurality of upper rolls arranged in one direction to raise and lower the gap between the upper and lower rolls And a segment control unit for controlling the operation of the cylinder. In general, since the lower roll is fixed and the upper roll is raised and lowered, the gap between the upper roll and the lower roll varies according to the height of the upper roll by the cylinder. In addition, the gap between the target upper roll and the lower roll may vary according to the product or process conditions to be manufactured. Accordingly, at least one of the upper roll and the lower roll is raised or lowered according to the product or process conditions so as to obtain a target gap. In the following description, a target gap is referred to as a reference value for convenience of description.

The comparison unit 420 compares the reference value and the calculation value. The adjusting unit 410 receives the result compared by the comparing unit 420 and controls the segment controller or the cylinder to move up and down at least one of the upper and lower rolls so that the reference value and the calculated value correspond.

When the gap is adjusted by raising and lowering at least one of the upper roll and the lower roll, the gap between the upper roll and the lower roll is measured again by a gap measuring apparatus according to the embodiment, and compared with a reference value. That is, the gap between the upper roll and the lower roll is measured again through the gap measuring unit 300, and the measured data is calculated as the actual gap between the upper roll and the lower roll by the calculating unit 430 of the control module 400. After that, it is transmitted to the comparator 420. Thereafter, the measurement is terminated when the calculated value corresponds to the reference value. On the contrary, when the calculated value does not correspond to the reference value, the adjusting unit 410 adjusts the gap by raising and lowering at least one of the upper and lower rolls.

On the other hand, the gap of the upper roll and the lower roll according to the operating value or the operating size of the cylinder is set in the control unit of the segment, the operator can move the cylinder by a corresponding value to maintain the desired gap. However, the gap between the upper roll and the lower roll and the actual gap of the upper roll and the lower roll may be different according to the operation value or the size of the cylinder according to the cylinder malfunction, damage to the upper roll and the lower roll. Therefore, using the gap measuring device according to an embodiment of the present invention, there is an advantage that can recognize the malfunction or damage of the controller, the upper roll or the lower roll of the segment.

7A to 7E and 8A and 8B are diagrams sequentially illustrating an operation of measuring a gap between an upper roll and a lower roll of a segment using a gap measuring apparatus according to an exemplary embodiment of the present invention. 9A and 9B are cross-sectional views for explaining the operation of the gap measuring unit when the gap measuring unit is positioned between the upper roll and the lower roll to measure the gap between the upper roll and the lower roll. 7A to 7E are views illustrating a process of setting a 'zero' point of a setting device and a gap measuring unit, and FIGS. 8A and 8B are examples of the present invention between an upper roll and a lower roll. It is a figure which shows the state which installed the gap measurement unit.

Hereinafter, an operation of measuring a gap between an upper roll and a lower roll of a segment using a gap measuring apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 to 9B. In this case, the content overlapping with the above-described content is briefly described or omitted.

First, the 'zero' point of the setting device 200 is set. To this end, a first standard S1 of height h1 and a second standard S2 of height h2 are prepared. Here, the first standard S1 may be, for example, a plate having a rectangular cross section, and the height h1 of the plate is, for example, 20 mm. The second standard S2 has a columnar shape extending in the vertical direction, and the height h2 is 100 mm. When the first and second standards S1 and S2 are provided, as shown in FIG. 7A, the first standard S1 is seated on the mounting member 210 of the setter 200, and the first standard is mounted. The second standard S2 is seated on S1. At this time, by operating the lever 260 to adjust the height of the micrometer 230, the end of the micrometer 230 is in contact with the upper end of the second standard (S2). And set it to '0 (zero)'.

Subsequently, the 'O (Zero)' point of the gap measurement unit 300 provided separately is set. To this end, first, as shown in FIG. 6A, the operator rotates the operation unit 348 counterclockwise. Thus, while the driving member 347-3 connected to the operation unit 348 rotates in the counterclockwise direction, the slide block 345 moves horizontally in the direction in which the operation unit 348 is located. At this time, the insertion member 345-2 of the slide block 345 moves horizontally while being inserted into the space between the upper rotating member 342a-1 and the lower rotating member 342b-1. Accordingly, the upper rotating member 342a-1 is raised while rotating along the upper inclined surface 345-2a of the inserting member 345-2, and the lower rotating member 342b-1 is inserted into the inserting member 345-2. It descends while rotating along the lower inclined surface 345-2b. Therefore, as shown in FIG. 7B, the upper tip 342a-3 connected to the upper rotating member 342a-1 is raised, and the lower tip 342b-3 connected to the lower rotating member 342b-1 is lowered. do. At this time, it is preferable to rotate the operation unit 348 so that the upper tip 342a-3 rises to the maximum height.

Then, the lower elevating member 342b-2 is pushed upward, so that the upper elevating member 342a-2 protrudes to the upper side of the upper opening 311-1 of the housing 310 as shown in FIG. 7C. do. At this time, for example, the operator's hand is inserted into the groove 311-4 provided in the lower portion of the housing 310, and the lower lifting member 342b-2 positioned above the groove 311-4 is upward. Push it up. Thus, as well as the lower tip 342b-3 and the lower elevating member 342b-2, the lower rotating member 342b-1, the slide block 345, which is installed on the upper elevating member 342b-2, The driving unit 347, the upper rotating member 342a-1, the upper elevating member 342a-2, and the upper tip 342a-3 rise. At this time, the lower lifting member 342b-2 is raised so as not to protrude outside the lower opening 311-2 provided in the housing 310.

Thereafter, as shown in FIG. 7D, the gap measuring unit 300 is seated on the seating member 210 of the setter 200. The lower tip 342b-3 contacts the upper surface of the first standard S1, and the upper tip 342a-3 contacts the lower end of the micrometer 230, and then presses the button 350. Set this to '0 (zero)' point. As described above, the height of the first standard (S1) is h1 (20mm), the lower tip 342b-3 of the gap measuring unit 300 is in contact with the upper surface of the first standard (S1), the upper Since the tip 342a-3 is installed to be in contact with the lower end of the micrometer 230, the separation distance between the upper end of the upper tip 342a-3 and the lower end of the lower tip 342b-3 is h2 (100 nm). to be. That is, h2 is set to '0 (zero)' point. The set '0' is transmitted to the measuring unit 349 and the calculating unit 430 of the control module 400.

Then, through the separation distance between the upper tip 342a-3 and the lower tip 342b-3 changed from h2 or 'zero' in measuring the gap between the upper roll RA and the lower roll RB. The lifting distance of the upper tip 342a-3 and the lower tip 342b-3 may be detected.

In this way, a plurality of 'zero' points of, for example, four gap measuring units 300 are set.

When the setting of the zero point of the plurality of gap measuring units 300 is completed, as shown in FIG. 8, the plurality of gap measuring units are disposed between the plurality of upper rolls RA and the lower rolls RB of the segment. Install 300 each. For example, when the six upper rolls RA (RA1 to RA6) are arranged in one direction as shown in FIG. 8, for convenience of description, the six upper rolls RA (RA1 to RA6) are first to first. It is named 6 upper rolls (RA1 to RA6). In addition, when the six lower rolls (RB; RB1 to RB6) are arranged in one direction, for convenience of description, the six lower rolls (RB; RB1 to RB6) are first to sixth lower rolls (RB1 to RB6). Name it)). At this time, the gap measuring unit 300 according to the embodiment is provided with two gap measuring unit 300 to be spaced apart in the horizontal direction between the first upper roll (RA1) and the first lower roll (RB1), the sixth upper Two gap measuring units 300 are installed to be spaced apart in the horizontal direction between the roll RA6 and the sixth lower roll RB6.

As such, the plurality of gap measuring units 300 are spaced apart from each other between the plurality of upper rolls RA (RA; RA1 to RA6) and the plurality of lower rolls (RB; RB1 to RB6). ; RA1 to RA6) and the gap between the lower roll (RB; RB1 to RB6) can be measured. Thus, the gap can be accurately measured as compared to the gap between the upper roll and the lower roll at one point as in the related art, and the horizontality of the upper and lower rolls can be detected.

On the other hand, for example, as shown in FIG. 9A, the actual gap between the upper roll RA and the lower roll RB (h3) is the upper tip 342a-3 and the lower portion of the gap measuring unit 300. The gap h2 (zero point) between the tips 342b-3 may be small compared to 100 nm. In this case, when the gap measuring unit 300 is seated between the upper roll RA and the lower roll RB, the upper end of the upper tip 342a-3 contacts the upper roll RA and the lower tip 342b-. The lower end of 3) is in contact with the lower roll (RB). At this time, since the actual gap h3 between the upper roll RA and the lower roll RB is smaller than the gap h2 between the upper tip 342a-3 and the lower tip 342b-3, the upper roll RA and The lower roll RB presses each of the upper tip 342a-3 and the lower tip 342b-3. Accordingly, the upper tip 342a-3 and the upper elevating member 342a-2 are lowered by a predetermined distance, and as a result, the slide block 345 and the operation unit 348 are rotated as the upper rotating member 342a-1 rotates. Horizontally move in the opposite direction. Due to the horizontal movement of the slide block 345, the lower rotating member 342b-1 rotates along the lower inclined surface 345-2b of the slide block 345, thereby lowering and lowering member 342b-2. And the lower tip 342b-3 drops a predetermined distance. Thus, the separation distance between the upper tip 342a-3 and the lower tip 342b-3 is reduced. In this case, the measurement unit 349 calculates a change in the separation distance between the upper tip 342a-3 and the lower tip 342b-3, that is, a reduced separation distance, based on '0 (zero)'. Thereafter, the separation distance between the upper tip 342a-3 and the lower tip 342b-3 and the horizontal moving distance of the slide block 345 measured by the measuring unit 349 are transmitted to the operation unit 430 of the control module 400. do.

On the contrary, as shown in FIG. 9B, the actual gap (hereinafter h4) between the upper roll RA and the lower roll RB is the upper tip 342a-3 and the lower tip 342b− of the gap measuring unit 300. 3) the gap h2 between may be small compared to 100 nm. Here h4 is included in the + error range based on h2. In this case, when the gap measuring unit 300 is positioned between the upper roll RA and the lower roll RB, the actual gap h4 between the upper roll RA and the lower roll RB becomes the upper tip ( Since the gap is larger than the gap h2 between the 342a-3 and the lower tip 342b-3, when the gap measuring unit 300 is positioned between the upper roll RA and the lower roll RB, the upper tip The 342a-3 and the lower tip 342b-3 are not pressed by the upper roll RA and the lower roll RB, and are spaced apart from each other by elastic force. That is, the lower raising and lowering block 342b descends and the upper raising and lowering block 342a rises. When the upper tip 342a-3 is raised and the lower tip 342b-3 is lowered as described above, the upper rotating member 342a-1 and the lower rotating member 342b-1 move the inclined surface of the slide block 345. Since the slide block 345 is moved along the horizontal direction in the direction in which the operation unit 348 is located. In addition, the measurement unit 349 calculates a change in the separation distance between the upper tip 342a-3 and the lower tip 342b-3, that is, an increased separation distance based on 'zero'. Thereafter, the separation distance between the upper tip 342a-3 and the lower tip 342b-3 and the horizontal moving distance of the slide block 345 measured by the measuring unit 349 are transmitted to the operation unit 430 of the control module.

In the above, as shown in FIG. 9B, the actual gap (hereinafter h4) between the upper roll RA and the lower roll RB is the upper tip 342a-3 and the lower tip 342b− of the gap measuring unit 300. When it is smaller than the gap h2 between 3), the h4 is included in the + error range, for example. However, the present invention is not limited thereto, and h4 may not be included in the + error range. That is, the gap between the actual upper roll RA and the lower roll RB may be too wide. In this case, since the gap measuring unit 300 does not operate, the upper roll RA is lowered using a cylinder and then measured again.

In the operation unit 430, the separation distance between the upper tip 342a-3 and the lower tip 342b-3 measured by the measuring unit 349 of the gap measuring unit 300 and the horizontal moving distance of the slide block 345 are determined. Applied to the trigonometric function, it computes the gap between the upper roll RA and the lower roll RB.

The gap between the upper roll RA and the lower roll RB calculated by the calculator 430 is transmitted to the comparator 420 and compared with a reference value preset by the operator. In addition, the adjusting unit 410 operates the cylinder connected to the upper roll RA according to the result of the comparison in the comparing unit 420, thereby raising or lowering the upper roll RA between the upper roll RA and the lower roll RB. To adjust the gap. In addition, the gap between the upper roll RA and the lower roll RB is again measured using the gap measuring unit 300, and the upper roll RA is raised until the measured value, that is, the calculated value corresponds to the reference value. Or lower to adjust the gap.

In the above, the gap between the upper roll (RA) and the lower roll (RB) of the segment used in the continuous casting process has been described using the gap measuring device according to an embodiment of the present invention as an example. However, the present invention is not limited thereto and may be applied to various devices for measuring a gap between two objects spaced apart from each other.

200: setting device 300: gap measuring unit

Claims (13)

A gap measuring device for measuring a gap between an upper roll and a lower roll,
Spaced apart in the vertical direction and capable of raising and lowering the upper and lowering blocks and the lowering and lowering blocks; And
A slide block positioned on one side of the upper elevating block and the lower elevating block to move horizontally between the upper elevating block and the lower elevating block to elevate the upper elevating block and the lower elevating block;
A gap measuring unit having a;
And a control module configured to calculate an actual gap between the upper roll and the lower roll using a change in the separation distance between the upper lifting block and the lower lifting block and a horizontal movement distance of the slide block. The method according to claim 1,
The slide block has an upper inclined surface connected with the upper elevating block and a lower inclined surface connected with the lower elevating block,
The upper inclined surface is inclined downward toward the upper elevating block, the lower inclined surface is inclined upward toward the lower elevating block. The method according to claim 2,
The upper lifting block,
An upper rotating member rotating and lowering along an upper inclined surface of the slide block;
An upper elevating block connected to an upper portion of the upper rotating member;
An upper tip connected to the upper lifting block;
The lower lifting block,
A lower rotating member rotating and lowering along a lower inclined surface of the slide block;
A lower elevating block connected to a lower portion of the lower rotating member;
Gap measuring device comprising a lower tip connected to the lower lifting block. The method according to claim 3,
If the slide block is moved horizontally in the direction in which the upper and lower lifting blocks,
The upper rotating member rises along the upper inclined surface of the slide block,
The lower rotating member is lowered along the lower inclined surface of the slide block ,
If the slide block is moved horizontally in the opposite direction to the upper lifting block and lower lifting block,
The upper rotating member descends along the upper inclined surface of the slide block,
The lower rotating member rises along the lower inclined surface of the slide block. The method according to claim 3,
And the upper tip and the lower tip are arranged to be orthogonal to the slide block. The method according to claim 1,
A driving unit provided extending from the other side of the upper elevating block and the lower elevating block, at least one end of which is fastened to the slide block through a space between the upper rotating member and the lower rotating member and is provided with a driving member that moves horizontally; Gap measuring device comprising. The method of claim 6,
And a stretchable elastic member connected to the drive member. The method of claim 6,
Gap measuring device is connected to the drive unit, comprising a control unit for rotating the drive unit. The method according to claim 3,
The control module
A calculation unit configured to calculate a gap between the upper roll and the lower roll using a change in the separation distance between the upper tip and the lower tip and a horizontal moving distance of the slide block;
A comparison unit comparing the operation value calculated by the operation unit with a reference value; And
And a control unit which raises and lowers at least one of the upper and lower rolls according to the result of comparison in the comparison unit. The method according to any one of claims 1 to 9,
The gap measuring unit is provided in plural, the gap measuring device which is spaced apart from each other between the upper roll and the lower roll, to measure the gap between the upper roll and the lower roll at each position. A slide for vertically moving the upper and lower lifting blocks and lower lifting blocks, horizontally moving between the upper and lower lifting blocks and the lower lifting blocks, and moving up and down the upper and lower lifting blocks. A gap measuring method using a gap measuring device including a gap measuring unit having a block and a control module interlocked with the gap measuring unit and measuring an actual gap between an upper roll and a lower roll,
The gap measuring unit is positioned between the upper roll and the lower roll so that the actual distance between the upper roll and the lower roll is changed by using the change of the separation distance between the upper lifting block and the lower lifting block and the horizontal movement distance of the slide block. A gap measurement method comprising calculating a gap. The method of claim 11,
And setting a zero point of the upper elevating block and the lower elevating block of the gap measuring unit. The method of claim 11,
And a plurality of the gap measuring units, wherein the plurality of gap measuring units are spaced apart from each other between the upper and lower rolls to measure gaps at a plurality of points.

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