Patent Application
20240271255
The present invention relates to a non-oriented electrical steel sheet having excellent magnetic properties, specifically having low eddy current loss in a high frequency range, and to a production method thereof.
From the viewpoint of not only increasing efficiency but also saving space and reducing weight, motors such as driving motors of electric vehicles (EVs), hybrid electric vehicles (HEVs), etc. and motors used for compressors of high-efficiency air conditioners are required to be small in size and aimed to achieve higher-speed rotation to secure output. As the material of the iron cores of these motors, non-oriented electrical steel sheets that are a soft magnetic material are mainly used.
An iron core material has an excitation frequency that is proportional to the motor speed. Therefore, when designing a high-speed motor, there is a problem, such as the increase in iron loss and decrease in motor efficiency associated with high speed rotation. In addition, such a motor is often driven by PWM control using an inverter instead of sinusoidal waveform, and the excitation waveform of the iron core contains harmonics of approximately 1 to 10 kHz, which also leads to a problem including the increase in iron loss resulted by these harmonics. To solve these problems, there is a strong need to reduce iron loss in the high-frequency range in non-oriented electrical steel sheets, which are used for iron cores.
An iron loss W of a non-oriented electrical steel sheet is the sum of a hysteresis loss Wh and an eddy current loss We, and these losses are proportional to the first power and the second power, respectively, of the frequency, so that the eddy current loss We becomes dominant in a high frequency range. As a countermeasure, reducing the eddy current loss by increasing the alloy content has been hitherto explored (e.g., see Patent Literatures 1 and 2).
While increasing the alloy content is effective means for reducing the iron loss of a non-oriented electrical steel sheet in a high frequency range, it also increases the strength of steel, which raises another problem that the steel sheet becomes difficult to cold-roll. As a solution, Patent Literature 1 proposes adopting warm rolling for cold rolling, and Patent Literature 2 proposes using Mn to restrain the increase of the strength of steel.
However, the warm rolling proposed in Patent Literature 1 has a problem that the steel sheet after rolling is poorly shaped when the temperature of the steel sheet at the start of rolling is raised too much, which puts a limit on applying this technique to industrial production. The method of using Mn proposed in Patent Literature 2 requires a large amount of Mn to be added to achieve a sufficient iron loss reducing effect, and thus faces problems such as that the raw material cost increases and that the iron loss tends to become unstable due to generation of Mn carbide.
Aspects of the present invention have been devised in view of the above-described problems with the prior art, and an object thereof is to reduce the eddy current loss in a high frequency range by means other than increasing the alloy content and thereby provide a non-oriented electrical steel sheet having high strength as well as low iron loss in a high frequency range, and to propose an advantageous production method thereof.
To solve the above-described problems, the present inventors have focused on a technique of reducing the iron loss by applying tensile stress to a steel sheet that is employed for grain-oriented electrical steel sheets and vigorously conducted a study to utilize the technique to reduce the eddy current loss in a non-oriented electrical steel sheet. As a result, we found that controlling the value of stress remaining in a product steel sheet within an appropriate range could reduce the eddy current loss in a high frequency range, and eventually developed the present invention.
Aspects of the present invention based on this insight include a non-oriented electrical steel sheet characterized in that an average ferrite grain size is 50 μm or larger and that compressive residual stresses σs and σc in a sheet width direction at a steel sheet surface and a sheet-thickness center part, respectively, measured by an X-ray stress measurement method are each 2.0 MPa or higher, wherein, as the X-ray stress measurement method, a 2θ−sin2 ψ method using an α-Fe (211) peak is used.
The above-described non-oriented electrical steel sheet according to aspects of the present invention is characterized by having an ingredient composition containing C: 0 to 0.0050 mass %, Si: 2.0 to 5.0 mass %, Mn: 0 to 3.0 mass %, P: 0 to 0.2 mass %, S: 0 to 0.0050 mass %, Al: 0 to 3.0 mass %, N: 0 to 0.0050 mass %, Cr: 0 to 3.0 mass %, and O: 0 to 0.0050 mass %, with the rest composed of Fe and inevitable impurities.
The above-described non-oriented electrical steel sheet according to aspects of the present invention is characterized by further containing at least one group selected from the following Groups A to D, in addition to the above-described ingredient composition:
The above-described non-oriented electrical steel sheet according to aspects of the present invention is characterized by further containing at least one group selected from the following Groups E to I in addition to the above-described ingredient composition:
Further, aspects of the present invention include a production method of the non-oriented electrical steel sheet described in any of the above, in which a slab having any one of the above-described ingredient compositions is subjected to hot rolling, hot-band annealing, cold rolling, and finishing annealing in a continuous annealing furnace, characterized in that: a maximum reached temperature in the finishing annealing is set to be 900° C. or higher; an average cooling rate from a temperature (maximum reached temperature−50° C.) to 500° ° C. in a cooling process of the finishing annealing is set to 40° C./s or higher; and a parameter e/t defined from a plastic elongation ratio ε (%) in a rolling direction between before and after the finishing annealing and a soaking time t (s) in the finishing annealing is set to 0.10 or higher. Note that the plastic elongation ratio ε is an elongation ratio of nominal strain.
Aspects of the present invention can stably provide a non-oriented electrical steel sheet with a reduced eddy current loss, which leads to a decrease in an iron loss, in a high frequency range. Thus, aspects of the present invention contribute significantly to increasing the efficiency and reducing the size of driving motors of EVs, HEVs, etc. used in a high-frequency range and motors for compressors of high-efficiency air conditioners.
An experiment that led to the development of aspects of the present invention will be described.
In the field of grain-oriented electrical steel sheets, it is known that applying tensile stress to a steel sheet in a rolling direction subdivides the magnetic domains and reduces the eddy current loss. Therefore, as a method of reducing the eddy current loss in a non-oriented electrical steel sheet, the present inventors focused on applying residual stress to a product steel sheet. As a method of introducing residual stress into the product steel sheet, we adopted tension annealing in finishing annealing, and studied the influence of the residual stress on the iron loss properties by the following experiment.
Steel having an ingredient composition containing C: 0.0015 mass %, Si: 3.37 mass %, Mn: 0.40 mass %, P: 0.01 mass %, S: 0.0009 mass %, Al: 0.91 mass %, N: 0.0018 mass %, Cr: 0.02 mass %, and O: 0.0012 mass %, with the rest composed of Fe and inevitable impurities was produced in a vacuum melting furnace and cast into a steel ingot. Then, this steel ingot was hot-rolled into a 1.5 mm-thick hot-rolled sheet. Next, this hot-rolled sheet was subjected to hot-band annealing at 1000° C. for 30 seconds in an N2 atmosphere, and was then cold-rolled into a 0.3 mm-thick cold-rolled sheet. Then, this cold-rolled sheet was subjected to finishing annealing in an atmosphere of a mixed gas of H2:N2=3:7 as a vol % ratio, while tensile stress of 1 to 10 MPa was applied in the rolling direction of the cold-rolled sheet. In the finishing annealing, a soaking treatment of holding the cold-rolled sheet within a temperature range of a maximum reached temperature, which was set to 1000° C., to (maximum reached temperature−10° C.) for 1 to 30 seconds was performed, and then gas cooling from a temperature (maximum reached temperature−50° C.) to 500° C. at an average cooling rate of 50° C./s was performed to obtain a product sheet. In the process, marking off lines were scratched on the surface of the steel sheet before the finishing annealing in the sheet width direction, and the intervals between the marking off lines before and after the finishing annealing were measured to obtain a plastic elongation ratio ε (%) in the rolling direction from the difference between these intervals. Here, the plastic elongation ratio ε is an elongation ratio of nominal strain. In accordance with aspects of the present invention, the time of remaining within the temperature range of the maximum reached temperature to (maximum reached temperature−10° C.) is defined as a soaking time.
From the product sheet obtained as described above, 30 mm-wide and 100 mm-long Epstein test specimens were cut out in each of the rolling direction and the sheet width direction. The iron loss W at a maximum magnetic flux density of 0.1 T and a frequency f within a range of 50 Hz to 5 kHz was measured by a single-sheet magnetic measurement method.
Next, from the measured relationship between the frequency f and the iron loss value W, the hysteresis loss Wh and the eddy current loss We were separated using a dual-frequency method to be described below. First, the relationship between W/f and f in a range of 50 to 1000 Hz was plotted, and an approximate expression of W/f=af+b was obtained by the least squares method. Here, the coefficient a and the intercept b are constants. As the intercept b is a hysteresis loss per cycle, multiplying the intercept b by the frequency f yields the hysteresis loss Wh (f) at the frequency f. On the other hand, the eddy current loss We (f) is obtained by subtracting this hysteresis loss Wh (f) from the measured iron loss value W at the frequency f: We (f)=W−Wh (f). The result of this experiment was analyzed with attention paid to an eddy current loss We1/5k at a maximum magnetic flux density of 0.1 T and a frequency of 5 kHz as an index of the increase in iron loss due to harmonics.
Next, the present inventors explored the reason why setting ε/t to 0.10 or higher led to a lower eddy current loss as described above. As a result, we found that this decrease in eddy current loss is closely correlated with residual stress in the product sheet. Here, the residual stress is a value that was measured by an X-ray stress measurement method, and particularly, MSF-2M manufactured by Rigaku Corporation was used as the X-ray measurement device. Using a Cr tube (kβ filter: V) as the X-ray source with the output set to 30 kV×4 mV, X-ray scanning was performed on a region of 7 mm×7 mm in the surface of a test specimen by a 2−sin2 ψ method (iso-inclination v constant method), and a strength distribution near 2θ=156.4° corresponding to α-Fe (211) was measured. The angle ψ was set to 12, 16, 20, 24, 28, 32, 36, 40, 44, and 48°, and the angle of oscillation of ψ was set to within a range of ±3°. Next, diffraction angles 2θ that indicated a peak in the measured strength distribution were plotted in a 2θ−sin2 ψ diagram as diffraction angles 2θ at the respective angles ψ. The inclination of the resulting straight line was obtained by the least squares method, and the residual stress σ (MPa) was obtained using the following formula:
In the 2θ−sin2 ψ method, stress within a plane of the specimen in an arbitrary direction can be measured by changing the scanning plane of the X-ray. Measurement of the residual stress o was performed at two locations, a surface and a sheet-thickness center part, of the test specimen, and the residual stress at the surface and the residual stress at the sheet-thickness center part were represented by σs and σc, respectively. Measurement of the sheet-thickness center part was performed by removing a portion of the test specimen from the surface on one side to the center part by chemical grinding. Here, when the residual stress o is a positive value, this means that there is compressive residual stress in the material, and conversely, when it is a negative value, this means that there is tensile residual stress in the material.
While this mechanism has not yet been sufficiently clarified, the present inventors believe as follows.
When finishing annealing is performed on a steel sheet while tensile stress is applied thereto, at high temperatures, plastic deformation progresses concurrently with recrystallization and grain growth. Here, as the yield stress for plastic deformation varies depending on the crystal orientation, in a polycrystalline body, the amount of plastic strain introduced into the crystal grains is not uniform but varies among the crystal grains. Therefore, if a state can be created in which tensile residual stress occurs in <100> that is an easy axis of magnetization and compressive residual stress occurs in <110>, <111>, <112>, etc. that are other hard axes of magnetization, the magnetic domains would become subdivided and the eddy current loss would decrease. Such conditions would be realized through tension annealing of finishing annealing. In tension annealing of finishing annealing, it would be important to rapidly cool the steel sheet after plastically deforming it at a high temperature in a short time such that residual stress and strain are not released through recrystallization or recovery.
Aspects of the present invention have been developed based on this new insight.
Next, an ingredient composition that the non-oriented electrical steel sheet according to aspects of the present invention should have will be described.
C: 0 to 0.0050 Mass %
C is an ingredient that forms carbide in a product sheet by magnetic aging and deteriorates the iron loss. To restrict the magnetic aging, C should be within a range of 0 to 0.0050 mass %. A preferable range is 0.0001 to 0.0020 mass %.
Si: 2.0 to 5.0 Mass %
Si has an effect of enhancing the specific resistance of steel and reducing the iron loss. It also has an effect of enhancing the strength of steel through solid solution strengthening. From the viewpoint of achieving such a low iron loss and high strength, the lower limit of Si should be 2.0 mass %. On the other hand, when Si exceeds 5.0 mass %, rolling becomes difficult. Therefore, the upper limit should be 5.0 mass %. A preferable range is 3.5 to 5.0 mass %. From the viewpoint of securing a particularly excellent balance between strength and iron loss, a preferable range is 3.5 to 4.5 mass %.
Mn: 0 to 3.0 Mass %
Mn has an effect of enhancing the specific resistance of steel and reducing the iron loss. However, when Mn exceeds 3.0 mass %, it conversely worsens the iron loss through precipitation of carbonitride. Therefore, Mn should be added within a range of 0 to 3.0 mass %. To reliably achieve the aforementioned iron loss reducing effect, it is preferable that Mn be added at a ratio of 0.3 mass % or more, with the upper limit preferably being 2.0 mass % from the viewpoint of restricting the generation of carbonitride.
P: 0 to 0.2 Mass %
P is an ingredient used to adjust the strength of steel and can be added as appropriate. However, when P exceeds 0.2 mass %, steel becomes brittle and difficult to roll. Therefore, the content of P should be within a range of 0 to 0.2 mass %. In the case where P is not used for strength adjustment, the content is preferably less than 0.02 mass %, whereas in the case where P is used for that purpose, the content is preferably within a range of 0.02 to 0.10 mass %.
S: 0 to 0.0050 Mass %
S is a harmful ingredient that hinders the grain growth by precipitating fine sulfide and increases the iron loss. In particular, when S exceeds 0.0050 mass %, these adverse effects become pronounced. Therefore, the content of S should be within a range of 0 to 0.0050 mass %. A preferable upper limit is 0.0020 mass %.
Al: 0 to 3.0 Mass %
Al has an effect of enhancing the specific resistance of steel and reducing the iron loss. It also has an effect of enhancing the strength of steel through solid solution strengthening. However, when Al exceeds 3.0 mass %, rolling becomes difficult. Therefore, the content of Al should be within a range of 0 to 3.0 mass %. A preferable range is 1.2 to 3.0 mass %. From the viewpoint of securing a particularly excellent balance between strength and iron loss, a more preferable range is 1.2 to 2.5 mass %. On the other hand, Al is an ingredient that increases the likelihood of formation of cavities during casting and solidification. Therefore, when recyclability is emphasized, the content is preferably limited to 0.01 mass % or less.
N: 0 to 0.0050 Mass %
N is a harmful ingredient that hinders the grain growth by precipitating fine nitride and increases the iron loss. In particular, when N exceeds 0.0050 mass %, these adverse effects become pronounced. Therefore, the content of N should be within a range of 0 to 0.0050 mass %. A preferable upper limit is 0.0020 mass %.
Cr: 0 to 3.0 Mass %
Cr has an effect of enhancing the specific resistance of steel and reducing the iron loss. However, when Cr exceeds 3.0 mass %, it conversely worsens the iron loss through precipitation of carbonitride. Therefore, the content of Cr should be within a range of 0 to 3.0 mass %. When Cr is less than 0.3 mass %, the aforementioned iron loss reducing effect is low. Therefore, when iron loss is emphasized, Cr is preferably added at a ratio of 0.3 mass % or more. From the viewpoint of restricting the generation of carbonitride, a preferable upper limit is 2.0 mass %.
O: 0 to 0.0050 Mass %
O is a harmful ingredient that hinders the grain growth by forming oxide-based inclusions and increases the iron loss. In particular, when O exceeds 0.0050 mass %, these adverse effects become pronounced. Therefore, the content of O should be within a range of 0 to 0.0050 mass %. A preferable upper limit is 0.0020 mass %.
The non-oriented electrical steel sheet according to aspects of the present invention may further contain the following ingredients in addition to the above-described ingredients according to the required properties.
At Least One of Sn: 0 to 0.20 Mass % and Sb: 0 to 0.20 Mass %
Sn and Sb have an effect of improving the recrystallization texture and reducing the iron loss, and can be added as appropriate. However, there is no use in adding Sn and Sb at a ratio exceeding 0.20 mass %, as this effect saturates. Therefore, a preferable upper limit is 0.20 mass % each. A more preferable range is 0.005 to 0.01 mass % each.
At Least One Selected from Ca: 0 to 0.01 Mass %, Mg: 0 to 0.01 Mass %, and REM: 0 to 0.05 Mass %
Ca, Mg, and REM (rare-earth metal) form stable sulfide and reduce fine sulfide, and thus have an effect of improving the grain growth properties and thereby the iron loss. However, excessively adding these ingredients conversely increases the iron loss. Therefore, when adding these ingredients, preferable upper limits are Ca: 0.01 mass %, Mg: 0.010 mass %, and REM: 0.05 mass %. More preferable ranges are Ca: 0.001 to 0.005 mass %, Mg: 0.0005 to 0.003 mass %, and REM: 0.005 to 0.03 mass %.
The non-oriented electrical steel sheet according to aspects of the present invention may further contain the following ingredients within the following ranges in addition to the above-described ingredients.
At Least One of Cu: 0 to 0.5 Mass % and Ni: 0 to 0.5 Mass %
Cu and Ni are effective ingredients in enhancing the toughness of steel and can be added as appropriate. However, this effect will be saturated when Cu and Ni are added at a ratio exceeding 0.5 mass % each. Therefore, a preferable upper limit is 0.5 mass % each. A more preferable range is 0.01 to 0.1 mass % each.
At Least One of Ge: 0 to 0.05 Mass %, as: 0 to 0.05 Mass %, and Co: 0 to 0.05 Mass %
Ge, As, and Co are effective ingredients for enhancing the magnetic flux density and reducing the iron loss, and can be added as appropriate. However, there is no use in adding Ge, As, and Co at a ratio exceeding 0.05 mass % each, as this effect saturates. Therefore, a preferable upper limit is 0.05 mass % each. A more preferable range is 0.002 to 0.01 mass % each.
The non-oriented electrical steel sheet according to aspects of the present invention may further contain the following ingredients within the following ranges in addition to the above-described ingredients.
At Least One of Ti: 0 to 0.005 Mass %, Nb: 0 to 0.005 Mass %, V: 0 to 0.010 Mass %, and Ta: 0 to 0.002 Mass %
Ti, Nb, V, and Ta are harmful ingredients that form fine carbonitride and increase the iron loss, and particularly these adverse effects become pronounced when the above upper limit values are exceeded. Therefore, it is preferable that Ti, Nb, V, and Ta be contained within the following ranges: Ti: 0 to 0.005 mass %, Nb: 0 to 0.005 mass %, V: 0 to 0.010 mass %, and Ta: 0 to 0.002 mass %. More preferable upper limit values are Ti: 0.002 mass %, Nb: 0.002 mass %, V: 0.005 mass %, and Ta: 0.001 mass %.
At Least One of B: 0 to 0.002 Mass % and Ga: 0 to 0.005 Mass %
B and Ga are harmful ingredients that form fine nitride and increase the iron loss, and particularly these adverse effects become pronounced when the above upper limit values are exceeded. Therefore, it is preferable that B and Ga be added within the following ranges: B: 0 to 0.002 mass % and Ga: 0 to 0.005 mass %. More preferable upper limit values are B: 0.001 mass % and Ga: 0.002 mass %.
Pb: 0 to 0.002 Mass %
Pb is a harmful ingredient that forms fine Pb grains and increases the iron loss, and particularly these adverse effects become pronounced when 0.002 mass % is exceeded. Therefore, Pb is preferably contained within a range of 0 to 0.002 mass %. A more preferable upper limit value is 0.001 mass %.
Zn: 0 to 0.005 Mass %
Zn is a harmful ingredient that increases fine inclusions and increases the iron loss, and particularly these adverse effects become pronounced when 0.005 mass % is exceeded. Therefore, Zn is preferably contained at a content ratio within a range of 0 to 0.005 mass %. A more preferable upper limit value is 0.003 mass %.
At Least One of Mo: 0 to 0.05 Mass % and W: 0 to 0.05 Mass %
Mo and W are harmful ingredients that form fine carbide and increase the iron loss, and particularly these adverse effects become pronounced when the above upper limit values are exceeded. Therefore, Mo and W are preferably contained within the following ranges: Mo: 0 to 0.05 mass % and W: 0 to 0.05 mass %. More preferable upper limit values are Mo: 0.02 mass % and W: 0.02 mass %.
The rest of the non-oriented electrical steel sheet according to aspects of the present invention other than the above-described ingredients is substantially composed of Fe and inevitable impurities.
Ferrite Average Grain Size: 50 μm or Larger
To reduce the iron loss, the non-oriented electrical steel sheet according to aspects of the present invention is required to have an average ferrite grain size of 50 μm or larger. When the ferrite grain size is smaller than 50 μm, a decrease in motor efficiency due to the increased iron loss poses a problem. A preferable average grain size is 80 μm or larger. The average grain size refers to the value of average grain size (an average line segment length per crystal of a test line) as measured by the cutting method in a microstructure revealed by etching a cross-section along the sheet thickness perpendicular to the sheet width direction (a cross-section along the sheet thickness in the rolling direction) with a Nital solution or the like.
σs: 2.0 MPa or Higher, σc: 2.0 MPa or Higher
In the non-oriented electrical steel sheet according to aspects of the present invention, it is required that the compressive residual stress σs in the sheet width direction at the steel sheet surface and the compressive residual stress σc at the sheet-thickness center part obtained by the X-ray stress measurement method are both 2.0 MPa or higher. It is preferable that Øs be 5 MPa or higher and that σc be 5 MPa or higher. Here, the X-ray stress measurement method is a 2θ−sin2 ψ method using an α-Fe (211) peak, and the measured compressive stress is a value calculated from the lattice spacing in the {211} plane of Fe. The compressive stress detected here is a value calculated from the lattice spacing in the {211} plane of Fe, and it is presumed that tensile stress is conversely applied to the easy axis of magnetization <100> of each crystal grain. When the value of the residual compressive stress exceeds 100 MPa, micro-yielding occurs inside some crystal grains. Therefore, a preferable upper limit is 100 MPa.
The residual stress introduced in accordance with aspects of the present invention is required to be nearly uniform in the sheet thickness direction. This is because the advantageous effects according to aspects of the present invention cannot be obtained when the residual stress varies in the sheet thickness direction. For example, when compressive stress is applied to a surface layer of the steel sheet by shot-blasting, tensile stress conversely occurs at the sheet-thickness center part, so that the advantageous effects according to aspects of the present invention cannot be obtained.
Next, a production method of the non-oriented electrical steel sheet according to aspects of the present invention will be described.
A steel material (slab) used to produce the non-oriented electrical steel sheet according to aspects of the present invention can be produced by performing secondary refining, such as a vacuum degassing treatment, on molten steel produced in a converter, an electric furnace, or the like to adjust the ingredient composition to the one described above, and then performing a continuous casting method or an ingot making-blooming method.
Next, the above-described slab is hot-rolled into a hot-rolled sheet by a commonly known method and conditions. After subjected to hot-band annealing as necessary, this hot-rolled sheet is pickled, and one time of cold rolling, or two or more times of cold rolling with intermediate annealing between each rolling, is performed thereon to obtain a cold-rolled sheet of a final sheet thickness (product sheet thickness).
Next, to impart desired strength and magnetic properties to the cold-rolled sheet, finishing annealing is performed using a continuous annealing furnace. From the viewpoint of securing both iron loss reduction and productivity, preferable conditions of this finishing annealing are a maximum reached temperature of 900 to 1100° C. and a soaking time within a range of 1 to 120 seconds. A more preferable maximum reached temperature is within a range of 950 to 1050° C., and a more preferable soaking time is within a range of 1 to 30 seconds. From the viewpoint of restricting oxidation, the atmosphere during the finishing annealing is preferably a reducing atmosphere, such as an atmosphere of a dry H2—N2 mixture.
Here, the most important thing to obtain the advantageous effects according to aspects of the present invention is that it is necessary to set the parameter ε/t defined from the plastic elongation ratio ε (%) in the rolling direction between before and after the finishing annealing and the soaking time t (s) in the finishing annealing to 0.10 or higher. When this parameter ε/t is lower than 0.10, is so low that sufficient residual stress fails to be introduced into the steel sheet, or t is so long that residual stress disappears due to recovery. A preferable parameter ε/t is 0.15 or higher.
The plastic deformation behavior during the finishing annealing varies depending on the ingredient composition of the steel sheet, the finishing annealing conditions (the annealing temperature and the temperature rising time), and the line tension. Therefore, particularly in a steel sheet containing large amounts of Si and Al that have high strength at high temperatures, ε/t can be increased by raising the annealing temperature or increasing the line tension.
Another thing important in the finishing annealing is that it is necessary to set the average cooling rate from a temperature (maximum reached temperature−50° C.) to 500° C. in the cooling process after the soaking treatment to 40° C./s or higher so the residual stress introduced into the steel sheet in a high temperature range remains until room temperature is reached. When the average cooling rate in this temperature range is lower than 40° C./s, the residual stress introduced at a high temperature is released through recovery, so that the advantages according to aspects of the present invention cannot be obtained. A preferable average cooling rate is 50° C./s or higher.
As necessary, an insulation coating is applied to the steel sheet after the finishing annealing to obtain a product sheet. As the insulation coating, a commonly known organic, inorganic, or both organic and inorganic coating can be used, with none of them diminishing the advantageous effects according to aspects of the present invention.
Steel having an ingredient composition containing C: 0.0009 mass %, Si: 3.65 mass %, Mn: 0.5 mass %, P: 0.01 mass %, S: 0.0008 mass %, Al: 1.36 mass %, N: 0.0012 mass %, Cr: 0.1 mass %, Sn: 0.02 mass %, Sb: 0.01 mass %, and O: 0.0011 mass %, with the rest composed of Fe and inevitable impurities was produced by an ordinary refining process and continuously cast into a steel material (slab). Next, this slab was heated at a temperature of 1080° ° C. for 30 minutes, and was then hot-rolled into a 1.5 mm-thick hot-rolled sheet. Next, this hot-rolled sheet was subjected to hot-band annealing at 930° ° C. for 20 seconds, and was then pickled and cold-rolled into a cold-rolled sheet with a final sheet thickness (product sheet thickness) of 0.25 mm. Next, this cold-rolled sheet was subjected to finishing annealing in a continuous annealing furnace under the various conditions shown in Table 1. In the process, the plastic elongation ratio ε (%) between before and after the finishing annealing was measured by the above-described method.
From the finishing-annealed sheet thus obtained, 30 mm-wide and 280 mm-long test specimens with the length direction oriented in the sheet width direction were taken. The iron loss W1/5k was measured by an Epstein test, and the value of the eddy current loss We1/5k at 0.1 T and 5 kHz was calculated by the above-described method. The test specimens were also used to measure the iron loss W15/50 at 1.5 T and 50 Hz. Further, the residual stresses σs and σc in the sheet width direction of the finishing-annealed sheet were measured by the above-described method.
The results of these measurements are included in Table 1. According to these results, the non-oriented electrical steel sheets produced under conditions complying with the present invention each exhibited low values of the eddy current loss We1/5k and iron loss W15/50. By contrast, in the steel sheets No. 1 to 4 and 13 to 17, for each of which ε/t or the cooling rate in the finishing annealing was not appropriate, desired residual stress was not achieved and the eddy current loss We1/5k was not reduced. In the steel sheets No. 20 and 21 that are examples in which residual stress (compressive stress) was introduced to the steel sheet surface of the finishing-annealed sheet by shot-peening, σs became compressive stress and the eddy current loss We1/5k conversely increased. In the steel sheet No. 22, due to the maximum reached temperature of the finishing annealing lower than 900° C., the finer ferrite grain size and a good eddy current loss We1/5k were achieved, while the iron loss W15/50 deteriorated.
Steel having an ingredient composition containing the various ingredients shown in Table 2, with the rest composed of Fe and inevitable impurities was produced by an ordinary refining process and continuously cast into a steel material (slab). Next, this slab was heated at 1150° ° C. for 30 minutes and then hot-rolled into a 1.8 mm-thick hot-rolled sheet. Then, this hot-rolled sheet was subjected to hot-band annealing at 950° C. for 10 seconds, and was then pickled and cold-rolled into a cold-rolled sheet with a final sheet thickness (product sheet thickness) of 0.20 mm. Next, this cold-rolled sheet was subjected to a soaking treatment in a continuous annealing furnace for a soaking time of 10 seconds with a maximum reached temperature set to 1020° C., and was then subjected to finishing annealing under the condition of the average cooling rate from a temperature (maximum reached temperature−50° C.) to 500° ° C. being 55° C./s. In the process, the line tension applied to the steel sheet was changed to various values within a range of 1 to 10 MPa, and the plastic elongation ratio ε (%) between before and after the finishing annealing was measured by the above-described method.
From the finishing-annealed sheet thus obtained, 30 mm-wide and 280 mm-long test specimens with the length direction oriented in the sheet width direction were taken. The iron loss W1/5k was measured by an Epstein test, and the value of the eddy current loss We1/5k at 0.1 T and 5 KHz was calculated by the above-described method. The iron loss W15/50 at 1.5 T and 50 Hz was also measured. Further, the residual stresses σs and σc in the sheet width direction of the finishing-annealed sheet were measured by the above-described method.
The results of these measurements are included in Table 2. Since the iron loss varies greatly even among steel sheets of the same sheet thickness depending on the contents of Si and Al that have an influence on the specific resistance of steel, the superiority or inferiority of the eddy current loss We1/5k was evaluated by an iron loss reference value W defined by the following formula:
According to these results, the non-oriented electrical steel sheets produced under conditions complying with the present invention each exhibited low values of the eddy current loss We1/5k and the iron loss W15/50.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2021-111440 | Jul 2021 | JP | national |
This is the U.S. National Phase application of PCT/JP2022/025041, filed Jun. 23, 2022, which claims priority to Japanese Patent Application No. 2021-111440, filed Jul. 5, 2021, the disclosures of these applications being incorporated herein by reference in their entireties for all purposes.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2022/025041 | 6/23/2022 | WO |
