This application claims the benefit of Japanese Patent Application No.
2020-197912 filed on Nov. 30,2020 with the Japan Patent Office, the entire disclosure of which is incorporated herein by reference.
The present disclosure relates to a method of producing an amorphous alloy ribbon.
Amorphous alloy ribbons have become increasingly popular, for example, as iron core materials for transformers.
As a method of reducing anomalous eddy current loss of an amorphous alloy ribbon, there are known methods such as a method comprising mechanically scratching a surface of the amorphous alloy ribbon, and a laser scribing method comprising radiating a laser beam to a surface of the amorphous alloy ribbon to locally melt the surface and rapidly solidify the ribbon, thereby subdividing magnetic domains.
Japanese Examined Patent Application Publication No. H3-32886, for example, discloses a laser scribing method comprising radiating a pulse laser in a width direction of an amorphous alloy ribbon to locally and instantaneously melt a surface of the amorphous alloy ribbon, and then rapidly solidifying the ribbon to form a series of amorphized spots in the shape of a dotted line, thereby subdividing magnetic domains.
Japanese Unexamined Patent Application Publication No. S61-258404 discloses radiating a laser beam with the laser beam being swept in a width direction of an amorphous alloy ribbon while the amorphous alloy ribbon has a surface temperature of 300° C. or higher. This Patent Document discloses an example of radiating a laser beam to a free surface of the ribbon with a YAG pulse laser device while the amorphous alloy ribbon, which has rapidly solidified on a surface of a cooling roll, is in contact with the cooling roll. The cooling roll has a peripheral speed of 10 m/sec, and conditions for radiating the laser beam are: a laser power of 200 W; a frequency of 20 kHz; a beam diameter of 0.15 mm; and a sweeping speed of 25 m/sec.
Japanese Unexamined Patent Application Publication No. S61-29103 discloses a method of improving magnetic properties of an amorphous alloy ribbon, the method comprising locally and instantaneously melting a surface of an amorphous alloy ribbon, then rapidly solidifying and non-crystallizing again the ribbon, and thereafter annealing the ribbon. It is also described that laser irradiation conditions when a YAG laser is radiated to a free surface of the amorphous alloy ribbon to introduce a locally melted part are: a frequency of 400 Hz; a beam diameter of 0.2 mmφ; an output of 5 w; a line speed of 2 cm/sec; and a beam sweeping speed of 10 cm/sec.
Conventionally, efforts have been made to improve iron loss by radiating a laser to an amorphous alloy ribbon. The amorphous alloy ribbon, for example, is used as an iron core of a power converter such as a power transformer or a high frequency transformer. The amorphous alloy ribbon for a power transformer or a high frequency transformer is required to have high performance. However, simply having high performance does not mean wide acceptance in the market. For wide acceptance in the market, high productivity, and cost that is not excessive are required. High performance here means, for example, having a low iron loss, a low coercive force, and a low exciting power.
As mentioned above, it has been known that iron loss is improved by radiating a laser to the amorphous alloy ribbon. However, the laser-radiated amorphous alloy ribbon has not been widely available in the market. This is believed to be due to lack of productivity that can be accepted in the market.
In the present disclosure, it is desirable to provide a method of producing an amorphous alloy ribbon that enables efficient laser irradiation and high productivity.
The present disclosure comprises the following modes.
<1> A method of producing an amorphous alloy ribbon comprising: radiating a laser to an amorphous alloy ribbon while the amorphous alloy ribbon travels or is travelling, to thereby form laser irradiation marks on the amorphous alloy ribbon,
wherein the laser irradiation marks are linear marks formed in a width direction of the amorphous alloy ribbon, and the linear marks are formed in a longitudinal direction of the amorphous alloy ribbon with an interval left, and
wherein, when the amorphous alloy ribbon has a traveling speed of S1 m/sec and the laser has a scanning speed of S2 m/sec, the Si is 0.1 m/sec or more and 30 m/sec or less, the S2 is 1 m/sec or more and 800 m/sec or less, and S2/S1 is 3.0 or more.
<2> The method of producing an amorphous alloy strip according to <1>, wherein an angle difference between a scanning direction of the laser and a direction orthogonal to a traveling direction of the amorphous alloy ribbon is 30 degrees or less.
<3> The method of producing an amorphous alloy strip according to <1> or <2>, wherein a distance from a lens through which the laser is output to a surface of the amorphous alloy ribbon is 200 mm to 1200 mm.
<4> The method of producing an amorphous alloy strip according to any one of <1> to <3>, wherein the laser uses a CW (continuous wave) oscillation method.
<5> The method of producing an amorphous alloy strip according to <4>, wherein the laser using a CW (continuous wave) oscillation method has a laser output energy density of 5 J/m or more and 35 J/m or less.
<6> The method of producing an amorphous alloy strip according to any one of <1> to <3>, wherein the laser is a pulse laser.
<7> The method of producing an amorphous alloy strip according to <6>, wherein the pulse laser has a laser pulse output energy of 0.4 mJ to 2.5 mJ.
<8> The method of producing an amorphous alloy strip according to any one of <1> to <7>, wherein the amorphous alloy ribbon has a width of 30 mm to 300 mm, and a thickness of 18 μm to 35 μm.
<9> The method of producing an amorphous alloy strip according to any one of <1> to <8>, wherein the interval between the linear marks in the longitudinal direction of the amorphous alloy ribbon is 2 mm to 200 mm.
<10> The method of producing an amorphous alloy strip according to any one of <1> to <9>, wherein a mechanism for suppressing oscillation of the amorphous alloy ribbon is provided in front and rear of a portion of the amorphous alloy ribbon to be irradiated with the laser.
<11> The method of producing an amorphous alloy strip according to <10>, wherein the mechanism for suppressing oscillation of the amorphous alloy ribbon adjusts a traveling position of the amorphous alloy ribbon with a plurality of rolls.
<12> The method for producing an amorphous alloy strip according to any one of <1> to <11>, wherein the laser is radiated to the amorphous alloy ribbon while the amorphous alloy ribbon unwound from an amorphous alloy ribbon holding spool travels or is travelling.
According to the present disclosure, a method of producing an amorphous alloy ribbon that enables efficient laser irradiation and high productivity can be provided. Also, a high performance amorphous alloy ribbon can be obtained.
An example embodiment of the present disclosure will be described hereinafter with reference to the accompanying drawings, in which:
An embodiment of the present disclosure will be described in detail hereinafter. The present disclosure is not limited to the following embodiment, and can be practiced with appropriate modifications within the scope not departing from the spirit of the present disclosure.
When the embodiment of the present disclosure is described with reference to the drawings, descriptions on components and reference signs overlapping in the drawings may be omitted. The components shown in the drawings with the same reference signs mean that they are the same components. Dimensional ratios in the drawings do not necessarily represent the actual dimensional ratios.
In the present disclosure, a numerical range represented using “(from) . . . to . . . ” indicates a range encompassing respective numerical values described before and after “to” as a lower limit and an upper limit. In numerical ranges described stepwise in the present disclosure, an upper limit value or a lower limit value described in one numerical range may be replaced with an upper limit value or a lower limit value of another numerical range described stepwise. The upper limit value or the lower limit value described in a certain numerical range described in the present disclosure may be replaced with a value shown in Examples. In the present disclosure, a combination of two or more preferred modes is a more preferred mode.
A method of producing an amorphous alloy ribbon according to one embodiment of the present disclosure will be described by way of
The method of producing an amorphous alloy ribbon according to one embodiment of the present disclosure shown in
A path where the amorphous alloy ribbon travels is provided with a laser irradiation device 3. The laser irradiation device 3 radiates a laser 4 to the amorphous alloy ribbon. The amorphous alloy ribbon 2, which has been irradiated with the laser and on which laser irradiation marks have been formed, travels in the direction indicated by the arrow A. The laser irradiation marks are traces of the laser that has been radiated.
During forming of the laser irradiation marks on the amorphous alloy ribbon, it is preferable to radiate the laser with the amorphous alloy ribbon travelling in order to improve productivity.
For the purpose of improving productivity, a traveling speed of the amorphous alloy ribbon is set to 0.1 m/sec or more, preferably 1 m/sec or more, and more preferably 2 m/sec or more.
When the traveling speed of the amorphous alloy ribbon is too fast, it is difficult to stably radiate the laser, and the form of the laser irradiation marks is disturbed. Therefore, the traveling speed of the amorphous alloy ribbon is set to 30 m/sec or less, preferably 20 m/sec or less, more preferably 10 m/sec or less, and still more preferably 9 m/sec or less.
In order to radiate the laser to the traveling amorphous alloy ribbon to form intended laser irradiation marks, and for stable laser output, a scanning speed of the laser is set to 1 m/sec or more, preferably 2 m/sec or more, and more preferably 3 m/sec or more. Further, the scanning speed of the laser may be 10 m/sec or more, or 35 m/sec or more. Also, when the scanning speed of the laser exceeds 800 m/sec, it is difficult to stably radiate the laser to the traveling amorphous alloy ribbon, and the form of the laser irradiation marks is disturbed. Therefore, the scanning speed of the laser is set to 800 m/sec or less, preferably 500 m/sec or less, and more preferably 300 m/sec or less.
If the scanning speed of the laser is too slow or too fast with respect to the traveling speed of the amorphous alloy ribbon, the laser irradiation becomes unstable, and it becomes difficult to stably form the laser irradiation marks. As a result, it becomes difficult to form the intended laser irradiation marks while maintaining productivity. Therefore, when the traveling speed of the amorphous alloy ribbon is set to S1 m/sec and the scanning speed of the laser is set to S2 m/sec, S2/S1 is set to 3.0 or more, preferably 5.0 or more, more preferably 7 or more, and still more preferably 10 or more. In addition, S2/S1 is set to preferably 300 or less, and more preferably 100 or less.
It is preferable to set a distance, from a lens through which the laser of the laser irradiation device 3 is output to a surface of the laser-radiated amorphous alloy ribbon 2, to 200 mm to 1200 mm. This allows the traveling amorphous alloy ribbon 2 to form the intended laser irradiation marks. If the distance is less than 200 mm, the laser focal depth is shallow, and the laser is out of focus. Thus, the laser cannot be stably radiated. Also, if the distance exceeds 1200 mm, a laser beam diameter becomes wide, and the intended laser irradiation marks cannot be obtained. Accordingly, the distance is more preferably 250 mm or more, still more preferably 260 mm or more, still more preferably 270 mm or more, and still more preferably 300 mm or more. In addition, the distance is more preferably 1000 mm or less, and still more preferably 800 mm or less.
The distance from the lens through which the laser of the laser irradiation device 3 is output to the surface of the laser-radiated amorphous alloy ribbon 2 is shown by a reference sign B in
In the method of producing an amorphous alloy ribbon according to one embodiment of the present disclosure, the amorphous alloy ribbon 2 is conveyed via rolls 6 to 9. These rolls allow the amorphous alloy ribbon 2 to travel to an intended position. Therefore, arrangement and the number of rolls can be adjusted in accordance with the intended position.
Also, although not shown in
The rolls 7, 8 function as a mechanism that suppresses oscillation of the amorphous alloy ribbon 2 when the laser is radiated. Therefore, a distance between the rolls 7, 8 and a position where the laser is radiated on the amorphous alloy ribbon 2 (distance between the position where the laser is radiated on the amorphous alloy ribbon 2 and a position where the amorphous alloy ribbon 2 contacts the roll 7 or the roll 8) should not be too far. For example, it is preferable that the distance is within 200 mm.
The laser irradiation marks of the present disclosure are linear marks formed in a width direction of the amorphous alloy ribbon, and the linear marks are preferably formed in a longitudinal direction of the amorphous alloy ribbon with an interval left. The linear marks may be in the shape of a dotted line formed with a pulse laser, or in the shape of a line formed with a laser that uses a CW (continuous wave) oscillation method.
It is preferable that the interval between the linear marks in the longitudinal direction of the amorphous alloy ribbon (hereinafter, also referred to as line interval) is 2 mm to 200 mm. The line interval may be the shortest length between the adjacent linear marks. The line interval may be more preferably 3.5 mm or more, still more preferably 5 mm or more, still more preferably 10 mm or more, and still more preferably 15 mm or more. In addition, the line interval is more preferably 100 mm or less, still more preferably 80 mm or less, and still more preferably 60 mm or less. The line interval may be further narrowed to 50 mm or less, 40 mm or less, and 30 mm or less.
It is preferable that a pulse laser or a laser that uses a CW (continuous wave) oscillation method is used for the laser that forms the laser irradiation marks.
In the case of using the pulse laser, for example, the form of laser irradiation marks disclosed in WO2019/189813 can be used.
When the pulse laser is used, a laser irradiation mark is formed as a dotted linear mark including a series of dot-like laser irradiation marks arranged in the width direction of the amorphous alloy ribbon with an interval left. This dotted linear mark is plurally formed in a traveling direction of the amorphous alloy ribbon with an interval left.
It is preferable that the interval between the dot-like laser irradiation marks (hereinafter, spot interval) is 0.10 mm to 0.50 mm. By forming the laser irradiation marks at intervals as such, reduction in iron loss and reduction of increase in exciting power can be expected. In particular, it is effective in reduction of iron loss and exciting power measured under a condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T.
It is also preferable that the interval between the dotted linear marks in the traveling direction of the amorphous alloy ribbon (hereinafter, line interval) is 10 mm to 60 mm.
It is also preferable that, when the line interval is d1 (mm), the spot interval is d2 (mm), and a number density D of the dot-like laser irradiation marks is D=(1/d1)×(1/d2), the number density D is 0.05 pieces/mm2 to 0.50 pieces/mm2.
With the line interval and the number density as above, reduction in iron loss of the amorphous alloy ribbon and reduction of increase in exciting power can be expected. In particular, it is effective in reduction of iron loss and exciting power measured under the condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T.
It is preferable that a laser pulse output energy of the pulse laser is 0.4 mJ to 2.5 mJ.
Also, in the case of using the laser that uses a CW (continuous wave) oscillation method (hereinafter, also referred to as CW laser), the laser irradiation mark is a linear mark continuous in the width direction of the amorphous alloy ribbon. The linear mark may have an intermittent linear shape.
The linear mark by the CW laser is a trace of the radiated laser, and irregularities are formed on the surface of the amorphous alloy ribbon. It is preferable that, when the irregularities are evaluated in the traveling direction of the amorphous alloy ribbon, a difference HL between the highest point and the lowest point in a thickness direction of the amorphous alloy ribbon is 0.20 μm to 2.0 μm.
It is also preferable that HL×WL calculated based on the difference HL between the highest point and the lowest point of the linear mark and a line width WL of the linear mark is 6 μm2 to 180 μm2. The line width WL of the linear mark is a width of the linear mark in the traveling direction of the amorphous alloy ribbon. It is also preferable that the line width WL is 28 μm or more.
It is preferable that, when the interval between the mutually adjacent linear marks is a line interval, the line interval is 2 mm to 200 mm. By forming the linear marks at the line interval, reduction in iron loss and reduction of increase in exciting power can be expected. In particular, it is effective in reduction of iron loss and exciting power measured under the condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T.
The line interval is more preferably 3.5 mm or more, still more preferably 5 mm or more, still more preferably 10 mm or more, and still more preferably 15 mm or more. Also, the line interval is more preferably 100 mm or less, still more preferably 80 mm or less, and still more preferably 60 mm or less. The line interval may be further narrowed to 50 mm or less, 40 mm or less, and 30 mm or less.
It is preferable that the laser output energy density of the CW laser is 5 J/m or more and 35 J/m or less, more preferably 6 J/m or more, still more preferably 7 J/m or more, still more preferably 8 J/m or more, and still more preferably 10 J/m or more. Also, the laser output energy density of the CW laser is more preferably 31 J/m or less, still more preferably 30 J/m or less, still more preferably 28 J/m or less, and still more preferably 25 J/m or less. The laser output energy density is also referred to as laser line density.
When the CW laser is used in forming the laser irradiation marks, a YAG laser, a CO2 gas laser, a fiber laser, or a diode laser can be used as a laser beam source. Above all, a fiber laser is preferable since the fiber laser can stably radiate a high-quality laser beam for a long period of time. In the case of a single mode fiber laser, M2 (M square), which represents beam quality, is about 1.3 or less. In the fiber laser, a laser beam introduced into a fiber oscillates on the principle of FBG (Fiber Bragg Grating) by diffraction gratings at both ends of the fiber. Since the laser beam is excited in the elongated fiber, there is no problem of a thermal lens effect in which the beam quality is deteriorated due to a temperature gradient generated inside the crystal. Furthermore, since a fiber core is as thin as a few microns, the laser beam can propagate in a single mode even at a high output. Thus, the beam diameter is narrowed and a laser beam having a high energy density can be obtained. Moreover, since the focal depth is deep, laser irradiation marks can be accurately formed even on a wide ribbon (for example, a ribbon having a width of 300 mm or more).
When the CW laser is used, a wavelength of the laser beam is about 250 nm to 10600 nm, depending on the laser beam source. A wavelength of 900 nm to 1100 nm is suitable since the laser beam is sufficiently absorbed in an alloy ribbon.
It is preferable that the laser beam has a beam diameter of 10 μm or more and 500 μm or less, and more preferably 25 μm or more and 100 μm or less.
The above-described dotted linear mark or linear mark is formed in a direction along the width direction of the amorphous alloy ribbon. The width direction of the amorphous alloy ribbon indicates a direction orthogonal to the traveling direction of the amorphous alloy ribbon.
It is preferable that a ratio of a length of the linear mark to the total length in the width direction of the amorphous alloy ribbon is 10% to 50% in a direction from the center in the width direction to each end in the width direction. The “%” herein is used to represent the ratio when the entire length in the width direction of the amorphous alloy ribbon is 100%.
When the linear mark is tilted with respect to the width direction, not the length of the tilted linear mark itself but a value obtained by converting the length to a length in the width direction of the ribbon at a location where the linear mark is formed is defined as the length in the width direction of the linear mark.
If the ratio of the length of the linear mark is 50%, this means that the linear mark extends from the center in the width direction of the amorphous alloy ribbon to one end and the other end in the width direction. In other words, it is a state in which the linear mark is formed from one end to the other end in the width direction of the amorphous alloy ribbon.
If the ratio of the length of the linear mark is 10%, this means that the linear mark has a length of 10% of the amorphous alloy ribbon in the direction from the center in the width direction to each end in the width direction. That is, there is a linear mark having a 20% length of the length in the width direction of the amorphous alloy ribbon in a center region of the amorphous alloy ribbon. In other words, it means that the amorphous alloy ribbon has the linear mark formed at its each end in the width direction leaving a margin of 40% to the entire length in the width direction of the amorphous alloy ribbon.
It is preferable that the ratio of the length in the width direction of the linear mark to the entire length in the width direction of the amorphous alloy ribbon is 25% or more in the direction from the center in the width direction to each end in the width direction.
The linear mark is formed in the width direction of the amorphous alloy ribbon.
The width direction of the amorphous alloy ribbon is the direction orthogonal to the traveling direction of the amorphous alloy ribbon, and a direction perpendicular to the longitudinal direction of the long amorphous alloy ribbon.
In the present disclosure, “in the width direction of the amorphous alloy ribbon” is not limited to a direction perpendicular to the longitudinal direction of the long amorphous alloy ribbon. Even if there is a tilt with respect to the perpendicular direction, it is interpreted as corresponding to “in the width direction”.
In the present disclosure, it is preferable that “in the width direction” means that the linear mark is parallel to or forms an angle of 30 degrees or less in a direction perpendicular to the longitudinal direction of the amorphous alloy ribbon. This angle is more preferably 10 degrees or less.
Since the linear mark is formed in the width direction of the amorphous alloy ribbon, a scanning direction of the laser is the same as a forming direction of the linear mark.
The laser is radiated while the amorphous alloy ribbon is traveling. Therefore, strictly speaking, the forming direction of the linear mark and the scanning direction of the laser are not exactly the same. However, since the scanning speed of the laser is faster than the traveling speed of the amorphous alloy ribbon, the two directions are generally similar.
For example, in forming the linear mark in parallel to the width direction, it is preferable that the scanning direction of the laser is slightly tilted with respect to the width direction, in consideration of the traveling speed of the amorphous alloy ribbon.
It is preferable that an angle difference between the scanning direction of the laser and the direction orthogonal to the traveling direction of the amorphous alloy ribbon is 30 degrees or less, more preferably 10 degrees or less, and still more preferably 5 degrees or less.
The directions will be explained with reference to
It is preferable that the amorphous alloy ribbon is produced (cast) by a single roll method. The amorphous alloy ribbon produced by the single roll method has a surface that has been brought into contact with a cooling roll and rapidly solidified during casting (also referred to as “roll contact surface”) and a surface opposite to the roll contact surface (namely, a surface that has been exposed to the atmosphere during the casting, and is also referred to as “free solidified surface”).
The longitudinal direction of the amorphous alloy ribbon corresponds to a casting direction when the amorphous alloy ribbon is produced by a single roll method, which is a direction corresponding to a peripheral direction of the cooling roll. Also, the casting direction and the traveling direction are the same.
It is preferable that the amorphous alloy ribbon of the present disclosure has a width of 30 mm to 300 mm. If the width is 30 mm or more, productivity can be increased. More preferably, the width is 60 mm or more. It is not easy to produce a wide amorphous alloy ribbon and therefore, productivity tends to decrease if the width exceeds 300 mm. There is no particular limitation on the thickness of the amorphous alloy ribbon of the present disclosure, but the thickness is preferably 18 μm to 35 μm. If the thickness is 18 μm or more, it is advantageous in terms of suppressing waviness of the amorphous alloy ribbon and improving a space factor. If the thickness is 35 μm or less, it is advantageous in terms of suppressing embrittlement and magnetic saturation of the amorphous alloy ribbon. The thickness of the amorphous alloy ribbon is more preferably 20 μm to 30 μm.
There is no particular limitation on the chemical composition of the amorphous alloy ribbon of the present disclosure. However, it is preferable that the amorphous alloy ribbon has a chemical composition of a Fe based amorphous alloy (namely, chemical composition containing Fe (iron) as a main component) is preferred. For example, when the amorphous alloy ribbon comprises Fe, Si, B, and impurities, and a total content of Fe, Si, and B is 100 atom %, it is preferable that the chemical composition has a Fe content of 78 atom % or more, a B content of 10 atom % or more, and a total content of B and Si of 17 atom % to 22 atom %.
Impurities may include any element other than Fe, Si, and B. Specifically, for example, impurities may include C, Ni, Co, Mn, O, S, P, Al, Ge, Ga, Be, Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, and rare earth elements. One type of, or two or more types of these chemical elements may be present as impurities.
These impurity elements can be contained in a range of 1.5% by mass or less in total with respect to the total mass of Fe, Si, and B. The total content of the impurity elements is preferably 1.0% by mass or less, more preferably 0.8% by mass or less, and still more preferably 0.75% by mass or less. Within this range, the impurity elements may be added.
An amorphous alloy ribbon having a chemical composition of Fe82 Si4 B14, and having a thickness of 25 μm, and a width of 210 mm was produced by a single roll method.
The “chemical composition of Fe82 Si4 B14” here means a chemical composition which consists of Fe, Si, B, and impurities, and which has a Fe content of 82 atom %, a B content of 14 atom %, and a Si content of 4 atom % when a total content of Fe, Si, and B is 100 atom %.
The amorphous alloy ribbon was produced by retaining a molten metal having the chemical composition of Fe82 Si4 B14 at a temperature of 1300° C., then ejecting the molten metal through a slit nozzle onto a surface of an axially rotating cooling roll, and rapidly solidifying the ejected molten metal on the surface of the cooling roll.
The produced amorphous alloy ribbon was wound around a spool. As a result, an amorphous alloy ribbon holding spool was prepared.
The ambient atmosphere immediately below the slit nozzle, where a paddle of the molten metal was to be formed, on the surface of the cooling roll was a non-oxidative gas atmosphere.
The slit length and the slit width of the slit nozzle were 210 mm and 0.6 mm, respectively.
The material of the cooling roll was a Cu-based alloy, and the peripheral speed of the cooling roll was 27 m/sec.
The pressure at which the molten metal is ejected, and the nozzle gap (namely, a gap between the tip of the slit nozzle and the surface of the cooling roll) were adjusted so that a maximum cross-sectional height Rt (specifically, maximum cross-sectional height Rt measured along the casting direction of the produced material ribbon) on the free solidified surface of the produced material ribbon is 3.0 μm or less.
Next, as shown in
The linear marks 25 were formed in the width direction of the amorphous alloy ribbon 2, and an angle difference between a forming direction of the linear marks 25 and the longitudinal direction of the amorphous alloy ribbon 2 was 90 degrees (less than one-degree difference from 90 degrees). As described below, the scanning speed of the laser was about 33 times the traveling speed of the amorphous alloy ribbon, which is sufficiently fast.
In the present Example, the scanning direction of the laser, as shown by the arrow C1 in
The linear mark 25 was formed from one end to the other end in the width direction of the amorphous alloy ribbon 2.
This means that a ratio of a length in the width direction of the linear mark to a total length in the width direction of the amorphous alloy ribbon was 50% in a direction from the center in the width direction to each end in the width direction.
In the longitudinal direction of the amorphous alloy ribbon, an interval LP1 (line interval) of the mutually adjacent linear marks 25 was 20 mm.
A reference sign W1 indicates the width of the amorphous alloy ribbon. Here, W1 was 210 mm.
Irradiation conditions of the laser using the CW (continuous wave) oscillation method were as follows.
laser output energy density: 10 J/m
The laser oscillator used was a fiber laser (YLR-150-WC) of IPG Photonics Corporation. The laser medium of the laser oscillator was a glass fiber doped with Yb, and the oscillation wavelength was 1064 nm.
The laser spot diameter on the free solidified surface of the amorphous alloy ribbon 2 was adjusted to 63.0 μm. The beam diameter was adjusted using an f100 mm collimator lens as an optical component and an fθ lens having a focal length of 420 mm.
The beam mode M2 was 1.1 (single mode).
The incident diameter DL and the spot diameter DL0 satisfy a relationship of DL0=4λf/πDL (where λ represents the laser wavelength and f represents the focal length). Thus, as the focal length of the collimator lens increases (namely, as the incident diameter DL increases), the spot diameter DLO tends to decrease.
With this Example, the amorphous alloy ribbon was unwound from the amorphous alloy ribbon holding spool wound with the amorphous alloy ribbon with a total length of about 20000 m, and the laser irradiation marks were formed on the surface of the traveling amorphous alloy ribbon. In this Example, the laser irradiation marks could be formed while the amorphous alloy ribbon with a total length of 20000 m continuously travelled (or was travelling).
The amorphous alloy ribbon having the laser irradiation marks formed thereon was subjected to the following evaluation. Results of the evaluation are shown in Table 1.
<Measurement of Iron Loss CL>
The amorphous alloy ribbon having the laser irradiation marks formed thereon was subjected to measurement of the iron loss CL by sinusoidal excitation with an AC magnetic measuring instrument in two conditions including a condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T and a condition of a frequency of 60 Hz and a magnetic flux density of 1.50 T.
<Measurement of Exciting Power VA>
The amorphous alloy ribbon having the laser irradiation marks formed thereon was subjected to measurement of the exciting power VA by sinusoidal excitation with an AC magnetic measuring instrument in two conditions including a condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T and a condition of a frequency of 60 Hz and a magnetic flux density of 1.50 T.
<Measurement of Coercive Force Hc>
The amorphous alloy ribbon having the laser irradiation marks formed thereon was subjected to measurement of the coercive force Hc by sinusoidal excitation with an AC magnetic measuring instrument in two conditions including a condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T and a condition of a frequency of 60 Hz and a magnetic flux density of 1.50 T.
As shown in Table 1, the amorphous alloy ribbon of Example 1 had an iron loss of 0.099 W/kg under the condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T, and an iron loss of 0.110 W/kg under the condition of a frequency of 60 Hz and a magnetic flux density of 1.50 T. The amorphous alloy ribbon obtained had a low iron loss.
The amorphous alloy ribbon of Example 1 had a coercive force of 2.26 A/m under the condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T, and a coercive force of 2.38 A/m under the condition of a frequency of 60 Hz and a magnetic flux density of 1.50 T. The amorphous alloy ribbon obtained had a low coercive force.
The amorphous alloy ribbon of Example 1 had an exciting power of 0.182 VA/kg under the condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T, and an exciting power of 0.283 VA/kg under the condition of a frequency of 60 Hz and a magnetic flux density of 1.50 T. Increase in exciting power was suppressed.
As above, in Example 1, the amorphous alloy ribbon having a low iron loss, a low coercive force, and a low exciting power was obtained.
The traveling speed S1 of the amorphous alloy ribbon, the scanning speed S2 of the laser, and the distance from the lens through which the laser is output to the laser radiated surface of the amorphous alloy ribbon were changed to prepare amorphous alloy ribbons having laser irradiation marks formed thereon. Each amorphous alloy ribbon prepared had a total length of 20000 m.
Respective conditions and evaluation results of properties are shown in Table 1.
Comparative Example 1 is an example of an amorphous alloy ribbon that was not subjected to laser irradiation.
In Examples 1 to 8, the iron loss under the condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T was 0.130 W/kg or less. The amorphous alloy ribbons obtained had an extremely low iron loss. Also, the iron loss under the condition of a frequency of 60 Hz and a magnetic flux density of 1.50 T was 0.145 W/kg or less. The amorphous alloy ribbons obtained had an extremely low iron loss.
In Examples 1 to 8, the coercive force under the condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T was 3.00 A/m or less. The amorphous alloy ribbons obtained had an extremely low coercive force. Also, the coercive force under the condition of a frequency of 60 Hz and a magnetic flux density of 1.50 T was 3.10 A/m or less. The amorphous alloy ribbons obtained had an extremely low coercive force.
In Examples 1 to 8, the exciting power under the condition of a frequency of 60 Hz and a magnetic flux density of 1.45 T was 0.200 VA/kg or less. Increase in exciting power was suppressed. The exciting power tends to increase when the laser irradiation marks are formed on the amorphous alloy ribbon. In the present Examples, increase in exciting power could be suppressed. Also, the exciting power under the condition of a frequency of 60 Hz and a magnetic flux density of 1.50 T was 0.300 VA/kg or less. Under this measurement condition, increase in exciting power could be suppressed.
The linear mark of Example 1 was observed with a laser microscope, and the respective dimensions were measured. Specifically, a color 3D laser microscope VK-8710 (manufactured by KEYENCE Corporation) and a 50× objective lens CF IC EPI Plan 50X (manufactured by Nikon Corporation) (magnification of 1000× (objective lens 50××monitor magnification 20×)) were used to photograph the surface shape. The line width WL (width of the melted solidified part) was measured based on the optical photograph.
Also, irregularities on the surface of the linear mark were observed. A laser microscope (the aforementioned color 3D laser microscope VK-8710, with the same magnification) was used for observation. Specifically, a profile in the width direction of the linear mark was measured with the laser microscope. At this time, a width of about 30 μm was added to the front and the rear of the line width WL, and the profile therebetween (30 μm+line width WL+30 μm) was measured. Based on this profile, a height difference HL was measured. In a case where the profile was tilted, the tilt was linearly corrected for measurement, using the margin of 30 μm added to each of the front and the rear, so that the profile is in a horizontal direction.
As a result, the difference HL between the highest point and the lowest point of the linear mark of Example 1 was 0.73 μm, and the line width WL was 78.63 μm. HL×WL calculated based on the difference HL between the highest point and the lowest point of the linear mark and the line width WL of the linear mark was 57.40 μm2.
As above, according to the Examples of the present disclosure, the method of producing an amorphous alloy ribbon could be obtained that enables efficient laser irradiation and high productivity. Also, according to the Examples of the present disclosure, high performance amorphous alloy ribbons could be obtained.
Also, according to the Examples of the present disclosure, the laser is radiated to a long amorphous alloy ribbon, which continues to travel. Thus, high productivity is achieved. As above, the method of the present disclosure is a method of producing an amorphous alloy ribbon that enables efficient laser irradiation and high productivity. Further, the method of the present disclosure is a method that allows obtaining a high performance amorphous alloy ribbon.
Number | Date | Country | Kind |
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2020-197912 | Nov 2020 | JP | national |