KR102175847B1 - Apparatus for refining magnetic domains to grain oriented electrical steel - Google Patents

Abstract

The magnetic domain refining apparatus includes a pattern forming portion for forming magnetic domain refining patterns using a laser beam on a steel sheet moving in one direction, and a melt and a heel-up adjacent to the pattern forming portion and adjacent to the magnetic domain refining patterns formed on the steel sheet ( hill up) physically and a first heel-up removal unit for chemically polishing the surface of the steel sheet.

Description

Magnetic domain refinement device of grain-oriented electrical steel sheet {APPARATUS FOR REFINING MAGNETIC DOMAINS TO GRAIN ORIENTED ELECTRICAL STEEL}

The present description relates to a magnetic domain refinement apparatus for grain-oriented electrical steel sheets.

In general, a magnetic domain refining device of a grain-oriented electrical steel sheet is a device that minimizes iron loss of a grain-oriented electrical steel sheet by miniaturizing a magnetic domain in a grain-oriented electrical steel sheet.

Recently, a magnetic domain refinement apparatus of a grain-oriented electrical steel sheet has been used to form a magnetic domain refinement pattern in a groove shape on a grain-oriented electrical steel sheet using a laser beam.

However, the conventional magnetic domain refinement apparatus of a grain-oriented electrical steel sheet forms a magnetic domain refinement pattern in the form of a groove on the grain-oriented electrical steel sheet using a laser beam, so that the melt and hill-up generated by the melting of the steel sheet by the laser beam, There is a problem of increasing the iron loss of the grain-oriented electrical steel sheet and reducing the magnetic flux density.

An embodiment is to provide a magnetic domain refinement apparatus for a grain-oriented electrical steel sheet that removes melt, heel-up, and foreign matter generated in the grain-oriented electrical steel sheet even if a groove-shaped magnetic domain refinement pattern is formed on the grain-oriented electrical steel sheet using a laser beam. .

In addition, even if a groove-shaped magnetic domain refinement pattern is formed on a grain-oriented electrical steel sheet using a laser beam, a magnetic domain refinement device for a grain-oriented electrical steel sheet is provided that prevents an increase in the iron loss of the grain-oriented electrical steel sheet and a decrease in the magnetic flux density of the grain-oriented electrical steel sheet. I want to.

One side is a pattern forming portion for forming magnetic domain refinement patterns using a laser beam on a steel sheet moving in one direction, and a melt and hill-up adjacent to the pattern formation portion and adjacent to the magnetic domain refinement patterns formed on the steel sheet. It provides a magnetic domain refining apparatus of a grain-oriented electrical steel sheet including a first heel-up removal unit that physically removes up) and chemically polishes the surface of the steel sheet.

The first heel-up removal unit may include a first foreign material removal cleaner inclined in one direction and in contact with the steel plate, a solution spraying part adjacent to the first foreign material removal cleaner, and spraying an acidic solution on the steel sheet, the solution spraying part, and A steam injection unit that is adjacent to and injects steam onto the steel plate, and a suction unit that is adjacent to the steam injection unit and sucks substances located on the steel plate.

The first heel-up removal unit may further include a second foreign matter removal cleaner adjacent to the suction unit and inclined in a direction opposite to the one direction to contact the steel plate.

The first heel-up removal unit may further include an exposure prevention cover adjacent to the first foreign matter removing cleaner to cover the steel plate, passing through the solution injection unit and the steam injection unit, and communicating with the suction unit.

The first heel-up removal unit may further include a guide plate blocking a side portion of the exposure prevention cover in correspondence with an edge of the steel plate.

A second heel-up removing unit may further include a second heel-up removing unit adjacent to the first heel-up removing unit and physically removing the heel-up of the steel plate using a brush roll.

A cleaning unit adjacent to the second heel-up removal unit may further include a cleaning unit for cleaning the steel sheet using an alkali solution.

A laser room accommodating the pattern forming unit, a steel plate central control unit for controlling the center of the steel plate, and a steel plate tension control unit located between the steel plate central control unit and the laser room, and controlling the tension of the steel plate may be further included. .

According to an embodiment, a magnetic domain refinement device for a grain-oriented electrical steel sheet is provided that removes melt, heel-up, and foreign matter generated in the grain-oriented electrical steel sheet even if a groove-shaped magnetic domain refinement pattern is formed on the grain-oriented electrical steel sheet using a laser beam. .

In addition, even if a groove-shaped magnetic domain refinement pattern is formed on the grain-oriented electrical steel sheet by using a laser beam, a magnetic domain refinement device for grain-oriented electrical steel sheet is provided that prevents an increase in the iron loss of the grain-oriented electrical steel sheet and at the same time prevents the magnetic flux density decrease of the grain-oriented electrical steel sheet. do.

1 is a view showing an apparatus for refining a magnetic domain of a grain-oriented electrical steel sheet according to an embodiment.
FIG. 2 is a plan view showing a grain-oriented electrical steel sheet on which a magnetic domain fine pattern is formed by the pattern forming portion shown in FIG. 1.
3 is a cross-sectional view taken along line III-III of FIG. 2.
FIG. 4 is a plan view illustrating a first heel-up removal unit illustrated in FIG. 1.
5 is a cross-sectional view taken along V-V of FIG. 4.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. The present invention may be implemented in various different forms, and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description have been omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

In addition, throughout the specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated.

Hereinafter, an apparatus for refining a magnetic domain of a grain-oriented electrical steel sheet according to an exemplary embodiment will be described with reference to FIGS. 1 to 5.

1 is a view showing an apparatus for refining a magnetic domain of a grain-oriented electrical steel sheet according to an embodiment.

Referring to FIG. 1, in the magnetic domain refining apparatus of a grain-oriented electrical steel sheet according to an embodiment, a magnetic domain refining pattern in a groove shape is formed in a steel sheet 10 continuously moving in one direction using a laser beam LB. The steel sheet 10 may be moved from the previous process through the magnetic domain refinement device of the grain-oriented electrical steel sheet to a later process.

Here, the steel plate 10 may be a grain-oriented electrical steel plate, but is not limited thereto. In addition, the above-described pre-process and post-process may be various known processes for handling grain-oriented electrical steel sheets.

The magnetic domain refinement device of the grain-oriented electrical steel sheet includes a steel sheet central control unit 100, a steel sheet tension control unit 200, a laser room 300, a pattern forming unit 400, a first heel-up removal unit 500, and a second heel-up removal unit ( 600), and a clean unit 700.

The steel plate central control unit 100 controls the center of the steel plate 10. The steel plate central control unit 100 controls the center of the steel plate 10 moving in one direction in the width direction to be aligned.

The steel plate central control unit 100 includes a first steering roll 110, a second steering roll 120, a steel plate central position control system 130, and a meander measurement sensor 140.

The steel plate central control unit 100 is the first steering by the steel plate central position control system 130 according to the degree (meaning amount) of the center of the width direction of the steel plate 10 notified by the meandering measurement sensor 140 from the center of the overall line. The center of the steel plate 10 is controlled by adjusting the direction in which the steel plate 10 moves by rotating and moving the rotational shafts of the roll 110 and the second steering roll 120, respectively.

The steel plate central control unit 100 may control the meandering amount of the steel plate 10 within ±1mm.

The steel plate tension control unit 200 is located between the steel plate central control unit 100 and the laser room 300. The steel plate tension control unit 200 controls the tension of the steel plate 10 moving in one direction.

The steel sheet tension control unit 200 includes a first tension bridle roll 210, a second tension bridle roll 220, a steel sheet tension control system 230, and a tension measurement sensor 240.

In order to maintain the steel plate 10 at a set tension, the steel plate tension control unit 200 uses the first tension bridle by the steel plate tension control system 230 according to the tension of the steel plate 10 notified by the tension measurement sensor 240. The tension of the steel plate 10 is controlled by adjusting the rotational speed of each of the roll 210 and the second tension bridle roll 220.

The steel sheet tension control unit 200 may control the tension of the steel sheet 10 to 1kgf/mm ² to 4kgf/mm ² .

By including the steel plate central control unit 100 and the steel plate tension control unit 200, even if the steel plate 10 is moved at a high speed of 2 m/s or more, the magnetic domain for the steel plate 10 using the laser beam of the pattern forming unit 400 Refinement treatment can be easily performed.

The laser room 300 accommodates a pattern forming part 400 for forming a magnetic domain refinement pattern on the steel plate 10.

The laser room 300 includes an optical system lower frame 310, a first air curtain 320, a second air curtain 330, a positive pressure device 340, and a constant temperature and humidity controller 350. Meanwhile, the laser room 300 may further include an air shower booth that removes foreign substances attached to a user's body entering and exiting the laser room 300.

The optical system lower frame 310 separates the lower space of the optical system 430 through which the steel plate 10 passes and the upper space of the optical system 430 where the laser oscillator 420 and the optical system 430 are located, It prevents contamination of the upper space and helps to control temperature and humidity easily.

The first air curtain 320 blows air on the front and rear surfaces of the steel plate 10 entering the laser room 300 to block dust and the like that flow into the laser room 300.

The second air curtain 330 blows air on the front and rear surfaces of the steel plate 10 exiting from the laser room 300 to block dust and the like flowing into the laser room 300.

The positive pressure device 340 sets the internal pressure of the laser room 300 higher than the external pressure, thereby suppressing the introduction of external foreign substances into the laser room 300.

The constant temperature and humidity controller 350 controls the temperature and humidity of the laser room 300. The constant temperature and humidity controller 350 may control the temperature of the laser room 300 to 20 to 25 degrees and control the humidity to 50% or less.

The pattern forming unit 400 forms magnetic domain fine patterns on the steel plate 10 moving in one direction using a laser beam LB.

The pattern forming unit 400 includes a laser oscillator controller 410, a laser oscillator 420, an optical system 430, a laser scattered light shielding cooling block 440, a fume and molten iron dust collecting hood 450, and a brightness measurement sensor 460. , A distance measurement sensor 470, a steel plate support roll position control system 480, a steel plate support roll 490, a first deflector roll 495, and a second deflector roll 496.

The laser oscillator controller 410 turns on and off the laser oscillator 420 and is connected to the meandering measurement sensor 140. The laser oscillator controller 410 may turn on the laser oscillator under normal working conditions, and may turn off the laser oscillator 420 when the amount of meandering of the steel plate 10 is 15 mm or more.

The laser oscillator 420 oscillates a TEM ₀₀ continuous wave laser beam and transmits it to the optical system 430, and the optical system 430 irradiates the laser beam LB onto the steel plate 10.

The optical system 430 may control the laser scanning speed to adjust the irradiation interval of the laser beam LB in the moving direction of the steel plate 10, and rotate the optical mirror to adjust the irradiation angle of the laser beam LB.

The laser oscillator 420 oscillates a single mode continuous wave laser beam and transmits it to the optical system 430, and the optical system 430 is a laser beam having an energy density of 1.0J/mm ² to 5.0J/mm ² ( LB) can be transferred to the steel plate 10.

The laser scattered light shielding cooling block 440 prevents the laser scattered light flowing into the optical system 430 and prevents the optical system 430 from being deformed by heat.

The fume and molten iron dust collecting hood 450 sucks fume and molten iron generated when the steel sheet 10 is irradiated with a laser beam LB.

Meanwhile, the pattern forming part 400 may further include an air knife AK, in which fume generated when irradiating the laser beam LB flows into the optical system 430. The molten iron generated in the steel plate 10 by the laser beam LB is separated from the magnetic domain refinement pattern in the form of a groove.

The luminance measurement sensor 460 measures the luminance of the flame generated on the steel plate 10 by irradiating the laser beam LB.

The distance measurement sensor 470 measures the distance between the optical system 430 and the steel plate 10.

The steel plate support roll position control system 480 controls the position of the steel plate support roll 490.

The steel plate support roll position control system 480 is the distance between the optical system 430 and the steel plate 10 measured by the luminance measurement sensor 460 and the optical system 430 measured by the distance measurement sensor 470 and the brightness of the flame generated on the steel plate 10. In consideration of the position of the steel plate support roll 490 can be controlled.

The steel plate support roll position control system 480 may control the position of the steel plate support roll 490 so that the steel plate 10 is positioned within a depth of focus where the irradiation efficiency of the laser beam LB is high.

The steel plate support roll 490 supports the steel plate 10 to which the laser beam LB is irradiated.

The first deflector roll 495 and the second deflector roll 496 guide the steel plate 10 to the steel plate support roll 490. The first deflector roll 495 and the second deflector roll 496 may be switched to move the steel plate 10 to the steel plate support roll 490.

FIG. 2 is a plan view illustrating a grain-oriented electrical steel sheet on which a magnetic domain fine pattern is formed by the pattern forming portion shown in FIG. 1. 3 is a cross-sectional view taken along line III-III of FIG. 2.

Referring to FIGS. 2 and 3, groove-shaped magnetic domain refinement patterns 11 are formed on the surface of the steel plate 10 moving in one direction X by a laser beam of a pattern forming unit. The width L1 of the magnetic domain refinement patterns 11 may be 70 μm to 10 μm, and the depth L2 may be 3 μm to 30 μm. A heel-up 12 protruding to a certain height (L3) is formed on the edges of the magnetic domain refinement patterns 11 formed in a groove shape by a laser beam, and the molten material melted from the steel plate 10 by the laser beam is formed in the steel plate 10 Can be attached to the surface of.

As the magnetic domain refinement patterns 11 are formed on the steel plate 10 by the pattern forming part, the improvement rate of the iron loss of the steel plate 10 before and after heat treatment may be secured by 5% or more and 10% or more.

In addition, by adjusting the spacing of the magnetic domain refinement patterns 11 to 2 mm to 30 mm in one direction (X), the effect of the heat affected zone on the steel sheet 10 by the laser beam is minimized, and the laser By setting the irradiation angle of the beam in the range of ±4 degrees, it is possible to minimize the decrease in magnetic flux density of the steel plate 10 due to the formation of the magnetic domain refinement pattern 11 in the form of a groove.

Referring to FIG. 1, the first heel-up removing unit 500 is adjacent to the pattern forming unit 400. The first heel-up removal part 500 is located between the pattern forming part 400 and the second heel-up removal part 600. The first heel-up removal unit 500 physically removes the magnetic domain refinement patterns formed on the steel plate 10 and the neighboring melts and hill-ups, and at the same time, chemically polishes the surface of the steel plate 10 to obtain the melt and heel-ups. Is chemically removed.

Meanwhile, the first heel-up removal unit 500 may be accommodated in the laser room 300 or may be located between the second heel-up removal unit 600 and the cleaning unit 700.

FIG. 4 is a plan view illustrating a first heel-up removal unit illustrated in FIG. 1. 5 is a cross-sectional view taken along V-V of FIG. 4.

4 and 5, the first heel-up removal unit 500 includes a first foreign material removal cleaner 510, a solution injection unit 520, a steam injection unit 530, a suction unit 540, and a second foreign material. It includes a removal cleaner 550, an exposure prevention cover 560, a guide plate 570, and a steel plate roll 580.

The first foreign matter removing cleaner 510 is inclined in one direction, which is the moving direction of the steel plate 10, and contacts the steel plate 10. The first foreign matter removing cleaner 510 may include a metal having a lower hardness than the steel plate 10, but is not limited thereto and may include a rubber.

The first foreign matter removal cleaner 510 physically removes foreign matter, melt, and heel-up located on the steel plate 10 by inclined contact with the steel plate 10 supported by the steel plate roll 580 in one direction.

That is, the first step of removing the molten material and the heal-up is performed by the first foreign material removing cleaner 510.

The solution spraying part 520 is adjacent to the first foreign matter removing cleaner 510. The solution spraying unit 520 sprays an acidic solution onto the steel plate 10. The solution spraying unit 520 may adjust the volume and concentration of the acidic solution.

The steam injection unit 530 is adjacent to the solution injection unit 520. The steam injection unit 530 injects steam onto the steel plate 10.

The suction unit 540 is adjacent to the steam injection unit 530. The suction unit 540 sucks materials located on the steel plate 10.

The acidic solution sprayed by the solution spraying unit 520 and the steam sprayed by the steam spraying unit 530 dissolve small foreign substances and melts of 5 μm or less located on the steel plate 10, and the heel-up is chemically polished. Thereafter, materials located on the steel plate 10 are sucked and removed by the suction unit 540.

That is, the solution injection unit 520, the steam injection unit 530, and the suction unit 540 perform the two-step removal of the melt and the heal-up.

The second foreign matter removing cleaner 550 is adjacent to the suction unit. The second foreign matter removing cleaner 550 is inclined in a direction opposite to one direction, which is a moving direction of the steel plate 10, and contacts the steel plate 10. The second foreign matter removing cleaner 550 may include a metal having a lower hardness than the steel plate 10, but is not limited thereto and may include a rubber.

The second foreign matter removal cleaner 550 physically removes foreign matter, melt, and heel-up located on the steel plate 10 by inclined contact with the steel plate 10 supported by the steel plate roll 580 in a reverse direction in one direction.

That is, three-step removal of the melt and the heel-up is performed by the second foreign material removal cleaner 550.

The exposure prevention cover 560 covers the steel plate 10 adjacent to the first foreign material removal cleaner 510. The exposure prevention cover 560 passes through the solution injection unit 520 and the steam injection unit 530. The exposure prevention cover 560 communicates with the suction unit 540.

The guide plate 570 blocks the side of the exposure prevention cover 560 in correspondence with the widthwise edge of the steel plate 10.

The exposure prevention cover 560 and the guide plate 570 prevent acid fume or acid solution steam from leaking to the outside.

The steel plate roll 580 supports the rear surface of the steel plate 10 in correspondence with the first foreign material removing cleaner 510 and the second foreign material removing cleaner 550.

The first foreign matter removing cleaner 510 contacts the first foreign matter removing cleaner 510 in the same direction as the moving direction of the steel plate 10 to remove foreign matter, melted matter, and heel-up from the steel plate 10 in a first step. The acidic solution is sprayed through the master part 520 and the chemically removed melt, heel-up and acidic components are sucked into the suction part 540 by spraying the steam through the steam injection part 530 and removed in two steps, and the second foreign substance is removed. By contacting the cleaner 550 in the reverse direction, foreign matter, melt, and heel-up of the steel plate 10 are removed in three steps.

That is, the first heel-up removal unit 500 physically removes the magnetic domain refinement patterns formed on the steel plate 10 and neighboring melts and hill-ups twice, while chemically polishing the surface of the steel plate 10 The melt and heel-up are chemically removed once.

Again, referring to FIG. 1, the second heel-up removal unit 600 is adjacent to the first heel-up removal unit 500, and the steel plate 10 using the first brush roll 610 and the second brush roll 620 Heal up of and physically remove the melt.

The second heel-up removal unit 600 includes a first brush roll 610, a second brush roll 620, a current control system 630, a brush position control system 640, and a dust collection hood 650.

The first brush roll 610 and the second brush roll 620 are controlled by a current control system 630 that controls a motor current generated during rotation to a set target value. The distance between the first brush roll 610 and the steel plate 10 is controlled by the brush position control system 640. The heel-up and melt of the steel plate 10 removed by the first brush roll 610 and the second brush roll 620 are sucked and removed by the dust collecting hood 650.

The cleaning unit 700 is adjacent to the second heel-up removal unit 600 and cleans the steel plate 10 using an alkali solution.

The cleaning unit 700 includes a cleaning unit 710 and a filtering system 720.

In the cleaning unit 710, the steel plate 10 is cleaned using an alkali solution and an electrolysis reaction. At this time, the heel-up and melt remaining on the steel plate 10 are additionally removed. The filtering system 720 manages the iron content of the alkali solution by removing the heel-up and melt-removal material in the alkali solution supplied to the cleaning unit 710. The filtering system 720 may manage the iron content in the alkaline solution to 500 ppm or less.

The steel plate 10 that has passed the cleaning unit 700 may be moved to various known post processes.

As described above, the magnetic domain refining apparatus of a grain-oriented electrical steel sheet according to an exemplary embodiment forms magnetic domain refining patterns on the steel sheet 10 by using the laser beam LB including the pattern forming unit 400, the first heel-up agent. The magnetic domain refinement patterns formed on the steel plate 10 including the reject 500 and the neighboring melt and hill-up are physically removed, and the surface of the steel plate 10 is chemically polished to chemically remove the melt and the heel-up. To remove.

In addition, the magnetic domain refinement apparatus of a grain-oriented electrical steel sheet according to an embodiment physically removes the melt and the heel-up formed on the steel sheet 10 by a laser beam using the first heel-up removal unit 500 while chemically removing it, and then It is physically removed using the second heel-up removing unit 600, and then chemically removed using the cleaning unit 700.

That is, even if a groove-shaped magnetic domain refinement pattern is formed on the grain-oriented electrical steel sheet by using a laser beam, a magnetic domain refinement device for a grain-oriented electrical steel sheet is provided that easily removes melt, heel-up, and foreign matter generated in the grain-oriented electrical steel sheet.

In addition, even if a groove-shaped magnetic domain fine pattern is formed on the grain-oriented electrical steel sheet using a laser beam, the melt and heel-up are easily removed, thereby preventing the increase in iron loss of the grain-oriented electrical steel sheet and at the same time preventing the decrease in the magnetic flux density of the grain-oriented electrical steel sheet. A magnetic domain refinement device for grain-oriented electrical steel sheets is provided.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Pattern forming part 400, first heel-up removal part 500, first foreign matter removing cleaner 510, solution spraying part 520, steam spraying part 530, suction part 540, second foreign matter removing cleaner (550)

Claims (8)

A pattern forming unit for forming magnetic domain fine patterns on a steel sheet moving in one direction using a laser beam; And
A first heel-up removal unit that is adjacent to the pattern forming unit and physically removes the melt and hill-up adjacent to the magnetic domain refinement patterns formed on the steel sheet, and chemically polishes the surface of the steel sheet
Including,
The first heel-up removal unit,
A first foreign matter removal cleaner inclined in the one direction and in contact with the steel plate;
A solution spraying unit adjacent to the first foreign material removing cleaner and spraying an acidic solution onto the steel plate;
A steam injection unit adjacent to the solution injection unit and injecting steam onto the steel plate; And
A suction unit that is adjacent to the steam injection unit and sucks substances located on the steel plate
Magnetic domain refinement device of a grain-oriented electrical steel sheet comprising a. delete In claim 1,
The first heel-up removal unit,
The magnetic domain refinement apparatus of a grain-oriented electrical steel sheet further comprising a second foreign matter removal cleaner adjacent to the suction part and inclined in a direction opposite to the one direction to contact the steel sheet. In claim 1,
The first heel-up removal unit,
The magnetic domain refinement apparatus of a grain-oriented electrical steel sheet further comprises an exposure prevention cover adjacent to the first foreign material removal cleaner to cover the steel plate, through the solution injection unit and the steam injection unit, and communicating with the suction unit. In claim 4,
The first heel-up removal unit,
Magnetic domain refinement apparatus of a grain-oriented electrical steel sheet further comprising a guide plate blocking a side portion of the exposure prevention cover in correspondence with the edge of the steel sheet. In claim 1,
The magnetic domain refining apparatus of a grain-oriented electrical steel sheet, which is adjacent to the first heel-up removal part, further comprising a second heel-up removal part for physically removing the heel-up of the steel sheet using a brush roll. In paragraph 6,
The magnetic domain refining apparatus of a grain-oriented electrical steel sheet, which is adjacent to the second heel-up removal part, and further comprises a cleaning part that cleans the steel sheet using an alkali solution. In claim 1,
A laser room accommodating the pattern forming part;
A steel plate central control unit for controlling the center of the steel plate; And
A steel plate tension control unit located between the steel plate central control unit and the laser room and controlling the tension of the steel plate
Magnetic domain refinement device of a grain-oriented electrical steel sheet further comprising a.

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