(19)
(11)EP 3 358 022 A1

(12)EUROPEAN PATENT APPLICATION
published in accordance with Art. 153(4) EPC

(43)Date of publication:
08.08.2018 Bulletin 2018/32

(21)Application number: 16850289.6

(22)Date of filing:  21.09.2016
(51)International Patent Classification (IPC): 
C21D 8/12(2006.01)
C22C 38/04(2006.01)
C21D 1/26(2006.01)
(86)International application number:
PCT/CN2016/099566
(87)International publication number:
WO 2017/054665 (06.04.2017 Gazette  2017/14)
(84)Designated Contracting States:
AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR
Designated Extension States:
BA ME
Designated Validation States:
MA MD

(30)Priority: 28.09.2015 CN 201510624002

(71)Applicant: Baoshan Iron & Steel Co., Ltd.
Shanghai 201900 (CN)

(72)Inventors:
  • YAN, Yuanyuan
    Shanghai 201900 (CN)
  • LIANG, Gaofei
    Shanghai 201900 (CN)
  • CHENG, Guoping
    Shanghai 201900 (CN)
  • LIN, Changqing
    Shanghai 201900 (CN)

(74)Representative: Maiwald Patent- und Rechtsanwaltsgesellschaft mbH 
Elisenhof Elisenstraße 3
80335 München
80335 München (DE)

  


(54)CONTINUOUS ANNEALING METHOD FOR LOW COERCIVE FORCE COLD-ROLLED ELECTROMAGNETIC PURE IRON PLATE AND STRIP


(57) A continuous annealing method for low coercive force cold-rolled electromagnetic pure iron plate and strip. Control parameters of each stages in a continuous annealing process are as follows: 750-850°C at a heating stage; 750-850°C at a soaking stage, the soaking time is 100-150s; an outlet temperature of 575-675°C at a slow-cooling stage, the cooling speed in slow-cooling stage is 2.5-10°C/s; an outlet temperature of 380-420°C at a fast-cooling stage, the cooling speed of the fast-cooling stage is 15-25°C/s; and 270-310°C at an overaging stage. The annealing medium is a non-oxidizing atmosphere composed of H2 and N2. After annealing, the cold-rolled electromagnetic pure iron plate and strip is leveled and pressed such that the leveling elongation rate of the plate and strip is controlled within the range of 0.2±0.1%. The process of the continuous annealing method is simple, and the produced cold-rolled electromagnetic pure iron plate and strip can achieve an overall performance of low coercive force and good formability without further magnetic annealing.


Description

Technical Field



[0001] The invention relates to the field of metal material processing, particularly relates to a continuous annealing method for cold-rolled electromagnetic pure iron plate and strip (pure iron sheet strip) of low coercive force, high formability, without further magnetic annealing.

Background Art



[0002] The electromagnetic pure iron has characteristics of low coercive force, high magnetic permeability and excellent processing performance, and is an important functional soft magnetic material.

[0003] Traditional electromagnetic iron products are dispatched from factories in a softened annealed state. Only after these pure iron products are stamped into parts and magnetic annealed by the users to eliminate the lattice distortion of cold processing, the products can thus fully show magnetic properties. According to the national standard GB/T 6983-2008, the cold-rolled electromagnetic pure iron steel can be divided into four grades on the basis of the magnetic properties, from high to low: DT4(Hc≤96A/m), DT4A(Hc≤72A/m), DT4E(Hc≤48A/m), DT4C(Hc≤32A/m). In addition, the magnetic annealing process of electromagnetic pure iron are stipulated as follows: when the annealing is protected by vacuum or inert gases, the electromagnetic pure iron is heated to a temperature of 900±10°C with the furnace and kept for 1h, and then the electromagnetic pure iron is cooled to 500°C or less or room temperature at a cooling rate of less than 50°C/h and then discharged from the furnace; when annealing in a decarburization atmosphere, the electromagnetic pure iron is heated to 800°C with the furnace, and then heated to 900±10°C in no less than 2h and kept for 4h, and then the electromagnetic pure iron is cooled to 500°C or less or room temperature at a cooling rate of less than 50°C/h and then discharged from the furnace.

[0004] An important application of the cold-rolled electromagnetic pure iron sheet strip is magnetic shielding materials, such as magnetic shell of electrical relay. In the conventional process, the parts are stamped and formed, and then magnetic annealed for up to several hours, the problem is that the magentic shell parts are always large, which adds extra requirements for annealing equipment, the production capacity is usually limited by the furnace loading capacity, and thereby prone to resulting in making the magnetic annealing process become a bottleneck in the entire production process, which extends the product manufacturing and processing cycle, and increases the cost thereof. Therefore, the manufacturers hope to use the electromagnetic pure iron sheet strip having low coercive force(<100A/m) and high formability, and does not require further magnetic annealing, but the prior art has not yet reached this target.

[0005] Analysis of existing patents related to electromagnetic pure iron products is shown in Table 1. First of all, most of the patents are focused on the continuous improvement of magnetic properties of cold-rolled electromagnetic pure iron, wherein the magnetic properties of the material is improved through the adjustment of alloy composition, the optimization of hot-rolled and cold-rolled process, and the control of magnetic annealing stages. The patent CN103789609A claims a method of improving the purity of electromagnetic pure iron, wherein the impurity element is reduced by electroslag remelting of forging ingot. Patent CN104232856A is directed to the problem that the surface of the workpiece may be easily oxidized during the magnetic annealing process, wherein an improvement method of magnetic annealing the electromagnetic pure iron parts is proposed.
Table 1. Analysis of related patents of electromagnetic pure iron products
Publication NumberAlloy CompositionHot-Rolled ProcessCold-Rolled ProcessAnnealing ProcessProducts
CN1211625A Low Al Heating 1100-1250 °C --- Cover annealing 580 °C and kept for 5h; Magnetic annealing 850-910 °C and kept for 4h DT4E cold-rolled sheet
Final rolling 850-950 °C
Reeling 600-750 °C
CN1410580 Low Al Heating 1000-1250 °C Deformation >60% Continuous annealing 600-800 °C; Magnetic annealing 800-900 °C and kept for 2h DT4E cold-rolled sheet
  Final rolling 750-900 °C   
CN1775466 High Al Final rolling 830-890 °C Deformation 30-50% Magnetic annealing 900-980 °C and kept for 3-5h DT4C cold-rolled sheet
Reeling 680-750 °C
CN103205548A High Al Final rolling 860-1000 °C Deformation 30-40% Cover annealing 540-560 °C and kept for 6-8h; Magnetic annealing 1000-1100 °C and kept for >2h DT4C cold-rolled sheet
Reeling 700-800 °C
Publication NumberSummary Of The InventionProducts
CN103789609A High Al (electroslag remelting)→hot-rolled bar Electromag-netic pure iron bar without hair seam
CN104232856A magnetic annealing process of the formed parts: 850-900 °C, kept for 3-4h, protect with alumina powder to prevent oxidation Annealing method

Summary of the invention



[0006] The purpose of the present invention is to provide a continuous annealing method for low coercive force cold-rolled electromagnetic pure iron sheet strip. The process of the continuous annealing method is simple, and the produced cold-rolled electromagnetic pure iron sheet strip can achieve an overall performance of low coercive force and good formability without further magnetic annealing.

[0007] In order to achieve the above technical purpose, the present invention has the following technical solutions:
A continuous annealing method for low coercive force cold-rolled electromagnetic pure iron sheet strip, wherein the parameters of each stages in a continuous annealing furnace are controlled as follows: 750-850°C at a heating stage; 750-850°C at a soaking stage, with a soaking time being 100-150s; an outlet temperature of 575-675°C at a slow-cooling stage, with a cooling speed in slow-cooling stage being 2.5-10°C/s; an outlet temperature of 380-420°C at a fast-cooling stage, with a cooling speed of the fast-cooling stage being 15-25°C/s; and 270-310°C at an overaging stage. An annealing medium is a non-oxidizing atmosphere composed of H2 and N2. After annealing, the cold-rolled electromagnetic pure iron sheet strip is leveled and pressed such that a leveling elongation rate of the sheet strip is controlled within a range of 0.2±0.1%.

[0008] The thickness of the cold-rolled electromagnetic pure iron sheet strip is 0.5-3.0mm.

[0009] Further, the percent composition by mass of the elements of the cold-rolled electromagnetic pure iron sheet strip are: C≤0.005%, Si≤0.1%, Mn=0.1%∼0.5%, P≤0.02%, S≤0.003%, Al≤0.005 %or Al=0.1∼1.5%, B≤0.007%, [N]≤0.005%, [O]≤0.02%, and the rest is Fe and unavoidable impurities.

[0010] Further, the as-described cold-rolled electromagnetic pure iron sheet strip after annealing has a coercive force of 60-100A/m, a yield strength of not less than 120MPa, an elongation of not less than 35%.

[0011] Further, the hot-rolled processing parameters of the as-described cold-rolled electromagnetic pure iron sheet strip are: heating temperature of 1000∼1200°C; final rolling temperature of 750∼900°C; reeling temperature of 550∼720°C; cold-rolled reduction rate of within 30∼55%.

[0012]  The electromagnetic pure iron sheet strip prepared by the continuous annealing method in the present invention has the advantages of low coercive force, high formability without further magnetic annealing, and thus solves the following problems: the traditional cold-rolled electromagnetic pure iron material needs to be magnetic annealed after stamped into parts, while the magnetic annealing of large-size parts is limited by furnace loading capacity, additionally, the product manufacturing and processing cycle is long, and the cost is high.

[0013] The mechanism of the continuous annealing method for low coercive force cold-rolled electromagnetic pure iron sheet strip of present invention is as follows.

[0014] The low coercive force cold-rolled electromagnetic pure iron sheet strip of present invention is prepared by the continuous annealing method. Because of the large amount of lattice distortion in the ferrite grain caused by rolling process, a large movement resistance of magnetic domain exists in the lattice, high-temperature annealing can provide enough thermodynamic driving force for recrystallization to eliminate the lattice distortion of cold rolling. Furthermore, if the annealing time is too short, the crystalline grain growth is not sufficient and the coercive force of the material is not satisfactory. The soaking temperature for annealing is 750-850 °C and the time in soaking stage for annealing is 100-150s, thus can ensure the production efficiency under the premise of coercive force Hc<100A/m of material.

[0015] The leveling elongation rate of the cold-rolled electromagnetic pure iron sheet strip of present invention should be controlled within the range of 0.2±0.1%. The increase of magnetic domain resistance due to the crystal defect resulted from leveling and pressing significantly affects the coercive force, however, due to the intrinsic low yield strength of the pure iron, the high-temperature continuous annealing is prone to result in edge wrinkles and other quality defects, and therefore, moderate leveling and pressing is also a key step to ensure the quality of the product surface; on the basis of above factors, the reduction rate is controlled to no more than 0.3%.

[0016] In this invention, the specific chemical composition of the electromagnetic pure iron sheet strip suitable for the above annealing method must satisfy certain requirements. C, N, O, and S are extremely detrimental elements to the magnetism of pure iron, and the distribution of fine MnS, AlN precipitates and oxide inclusions may hinder the grain growth, strongly affect the magnetization, and increase the coercive force. Therefore, when applying the annealing process of present invention, the content of impurity elements should be minimized as much as possible while avoiding the formation of fine inclusions. Aluminum significantly affects the existence form of inclusions in the pure iron. The control of aluminum usually takes the measure using two extreme values for the following reasons: acid soluble aluminum (Als) in the range of 0.005-0.014% is prone to form fine AlN and thus prevent the growth of ferrite grain. when there are too many fine grain being exist, the orientations which is detrimental to magnetic properties will dramatically increase. However, when Als≤0.003%, as the aluminum content is reduced, the grains are coarsening and the orientations which is beneficial to magnetic properties increased. When the content of aluminum is above 0.15%, coarse AlN can also be formed, which improves the texture and reduces the magnetic anisotropy, and fixes N so as to reduce the magnetic aging.

[0017] In addition, with respect to the selection of hot-rolled process, higher final rolling and reeling temperatures are selected for the following reasons: on the one hand, higher final rolling and reeling temperatures are beneficial to the recovery, recrystallization and grain growth of the deformed hot-rolled structure, and promote the formation of coarse grain in the hot-rolled plate; on the other hand, higher final rolling and reeling temperatures are beneficial to the aggregation and growth of fine inclusions (such as AlN, MnS) in the steel, thereby reducing the interference of fine inclusions on the grain boundary movement during the heat treatment of the sample, and thus reducing the pinning effect on the magnetic domain movement.

[0018] Cold-rolled reduction rate should be controlled at 30∼55% and an excessive reduction rate should be avoid. During the cold-rolled process, different deformations will result in different deformed microstructures, which will affect nucleation and growth kinetics during the recrystallization. Low amount of cold-rolled deformation may introduce strain in the hot-rolled plate, and thereby induce grain boundary migration, promoting the growth of annealed grains and getting better magnetic properties. However, with the further increase of the amount of cold-rolled deformation, the complex slip regions increase, and cellular structure develops. Although both of the rates of recrystallization nucleation and grain growth increase, the nucleation rate will be greater than the grain growth rate, resulting in fine recrystallized grains, an increased corresponding coercive force Hc and worse magnetic properties.

[0019] The low coercive force cold-rolled electromagnetic pure iron sheet strip prepared by the continuous annealing method in present invention does not require further magnetic annealing. The index parameters of cold-rolled electromagnetic pure iron sheet strip after annealing are: a coercive force of 60-100A/m, a yield strength≥120MPa, an a elongation≥35%.

[0020] As the last stage of the production of cold-rolled electromagnetic pure iron sheet strip, the continuous annealing method for low coercive force cold-rolled electromagnetic pure iron sheet strip of the present invention has a simple process, and the cold-rolled electromagnetic pure iron sheet strip produced can achieve an overall performance of low coercive force and good formability without further magnetic annealing.

Detailed Description


Example 1



[0021] Components: the percent composition by mass of the elements of the strip steel is shown in Table 2, and the rest is Fe and unavoidable impurities. The strip thickness is 1.2±0.04mm.
Table 2: The mass percentages of the chemical composition of the strip steel of Example 1 (unit:%)
CSiMnPSAlBNO
0.0021 0.089 0.27 0. 016 0.003 0.001 0.0001 0. 002 0.015


[0022] Process: parameters in hot-rolled process: heating temperature 1150°C; final rolling temperature 850°C; reeling temperature 550°C; cold-rolled reduction rate 50%.

[0023] The specific processing parameters according to the annealing method of present invention are: 830±20°C at a heating stage; 830±20°C at a soaking stage, the soaking time is 140s; an outlet temperature of 675°C at a slow-cooling stage, the cooling speed in slow-cooling stage is 5°C/s; an outlet temperature of 400°C at a fast-cooling stage, the cooling speed of the fast-cooling stage is 25°C/s; and 300°C at an overaging stage; the annealing medium is a non-oxidizing atmosphere composed of H2 and N2. The leveling elongation rate of the annealed sheet strip is controlled within the range of 0.2±0.1%.

[0024] Implementation results: coercive force Hc of continuous annealing of cold-rolled electromagnetic pure iron sheet strip: 71A/m, yield strength: 159Mpa, elongation: 53.5%. It has good overall performance.

Example 2



[0025] Components: the percent composition by mass of the elements of the strip steel is shown in Table 3, and the rest is Fe and unavoidable impurities. The strip thickness is 2.0±0.04mm.
Table 3: The mass percentages of the chemical composition of the strip steel of Example 2 (unit:%)
CSiMnPSAlBNO
0.0019 0.003 0.18 0.019 0.003 0.55 0.0001 0.0019 0.005


[0026] Process: parameters in hot-rolled process: heating temperature 1150°C; final rolling temperature 870°C; reeling temperature 650°C; cold-rolled reduction rate 45%.

[0027] The specific processing parameters according to the annealing method of present invention are: 830±20°C at a heating stage; 830±20°C at a soaking stage, the soaking time is 130s; an outlet temperature of 675°C at a slow-cooling stage, the cooling speed in slow-cooling stage is 5°C/s; an outlet temperature of 400°C at a fast-cooling stage, the cooling speed of the fast-cooling stage is 25°C/s; and 300°C at an overaging stage; the annealing medium is a non-oxidizing atmosphere composed of H2 and N2. The leveling elongation rate of the annealed sheet strip is controlled within the range of 0.2±0.1%.

[0028] Implementation results: coercive force Hc of continuous annealing of cold-rolled electromagnetic pure iron sheet strip: 65A/m, yield strength: 155Mpa, elongation: 55%. It has a good overall performance.

Example 3



[0029] Components: the percent composition by mass of the elements of the strip steel is shown in Table 4, and the rest is Fe and unavoidable impurities. The strip thickness is 1.0±0.04mm.
Table 4: The mass percentages of the chemical composition of the strip steel of Example 3 (unit:%)
CSiMnPSAlBNO
0.0023 0.003 0.18 0.016 0.0036 0.001 0.0052 0.0021 0.013


[0030] Process: parameters in hot-rolled process: heating temperature 1200°C; final rolling temperature 900°C; reeling temperature 720°C; cold-rolled reduction rate 40%.

[0031] The specific processing parameters according to the annealing method of present invention are: 810±20°C at a heating stage; 810±20°C at a soaking stage, the soaking time is 110s; an outlet temperature of 650°C at a slow-cooling stage, the cooling speed in slow-cooling stage is 6°C/s; an outlet temperature of 400°C at a fast-cooling stage, the cooling speed of the fast-cooling stage is 25°C/s; and 300°C at an overaging stage; the annealing medium is a non-oxidizing atmosphere composed of H2 and N2. The leveling elongation rate of the annealed sheet strip is controlled within the range of 0.2±0.1%.

[0032] Implementation results: coercive force Hc of continuous annealing of cold-rolled electromagnetic pure iron sheet strip: 80A/m, yield strength: 157Mpa, elongation: 50.3%. It has a good overall performance.

Example 4



[0033] Components: the percent composition by mass of the elements of the strip steel is shown in Table 5, and the rest is Fe and unavoidable impurities. The strip thickness is 1.8±0.04mm.
Table 5: The mass percentages of the chemical composition of the strip steel of Example 4 (unit:%)
CSiMnPSAl.BNO
0.0030 0.003 0.18 0.019 0.003 0.002 0.0001 0.0016 0.017


[0034] Process: parameters in hot-rolled process: heating temperature 1120°C; final rolling temperature 870°C; reeling temperature 700°C; cold-rolled reduction rate 40%.

[0035] The specific processing parameters according to the annealing method of present invention are: 810±20°C at a heating stage; 810±20°C at a soaking stage, the soaking time is 130s; an outlet temperature of 675°C at a slow-cooling stage, the cooling speed in slow-cooling stage is 5°C/s; an outlet temperature of 400°C at a fast-cooling stage, the cooling speed of the fast-cooling stage is 25°C/s; and 300°C at an overaging stage; the annealing medium is a non-oxidizing atmosphere composed of H2 and N2. The leveling elongation rate of the annealed sheet strip is controlled within the range of 0.2±0.1%.

[0036] Implementation results: coercive force Hc of continuous annealing of cold-rolled electromagnetic pure iron sheet strip: 84A/m, yield strength: 165Mpa, elongation: 52%. It has a good overall performance.

Comparative example



[0037] Components: the percent composition by mass of the elements of the strip steel is shown in Table 6, and the rest is Fe and unavoidable impurities. The strip thickness is 1.8±0.04mm.
Table 6: The mass percentages of the chemical composition of the strip steel of Comparative example
CSiMnPSAlBNO
0.0030 0.003 0.18 0.019 0.003 0.002 0. 0001 0.0016 0.017


[0038] Process: parameters in hot-rolled process: heating temperature 1120°C; final rolling temperature 870°C; reeling temperature 700°C; cold-rolled reduction rate 40%.

[0039] Annealing method: 560±20°C at a heating stage; 560±20°C at a soaking stage, the soaking time is 100s; an outlet temperature of 500°C at a slow-cooling stage, the cooling speed in slow-cooling stage is 5°C/s; an outlet temperature of 370°C at a fast-cooling stage, the cooling speed of the fast-cooling stage is 25°C/s; and 280°C at an overaging stage; the annealing medium is a non-oxidizing atmosphere composed of H2 and N2. The leveling elongation rate of the annealed sheet strip is controlled within the range of 1.0±0.2%.

[0040] Implementation results: coercive force Hc of continuous annealing of cold-rolled electromagnetic pure iron sheet strip: 127A/m, yield strength: 213Mpa, elongation: 42%. The final products have an over-high coercive force, which cannot meet the requirements of the use of magnetic shielding materials.


Claims

1. A continuous annealing method for low coercive force cold-rolled electromagnetic pure iron sheet strip, wherein control parameters of each stages in a continuous annealing process are as follows: 750-850°C at a heating stage; 750-850°C at a soaking stage, with a soaking time being 100-150s; an outlet temperature of 575-675°C at a slow-cooling stage, with a cooling speed in slow-cooling stage being 2.5-10°C/s; an outlet temperature of 380-420°C at a fast-cooling stage, with a cooling speed of the fast-cooling stage being 15-25°C/s; and 270-310°C at an overaging stage; an annealing medium is a non-oxidizing atmosphere composed of H2 and N2; after annealing, the cold-rolled electromagnetic pure iron sheet strip is leveled and pressed such that a leveling elongation rate of the sheet strip is controlled within a range of 0.2±0.1 %.
 
2. The continuous annealing method for low coercive force cold-rolled electromagnetic pure iron sheet strip according to claim 1, wherein a thickness of the said cold-rolled electromagnetic pure iron sheet strip is 0.5-3.0mm.
 
3. The continuous annealing method for low coercive force cold-rolled electromagnetic pure iron sheet strip according to claim 1, wherein a percent composition by mass of the elements of the said cold-rolled electromagnetic pure iron sheet strip is: C<0.005 %, Si≤0.1%, Mn=0.1%∼ 0.5%, P≤0.02%, S≤0.003%, Al≤0.005% or Al=0.1∼1.5%, B≤0.007%, [N]<0.005 % , [O]≤0.02%, and the rest is Fe and unavoidable impurities.
 
4. The continuous annealing method for low coercive force cold-rolled electromagnetic pure iron sheet strip according to claim 3, wherein the said cold-rolled electromagnetic pure iron sheet strip after annealing has a coercive force of 60-100A/m, a yield strength of not less than 120MPa, a elongation of not less than 35%.
 
5. The continuous annealing method for low coercive force cold-rolled electromagnetic pure iron sheet strip according to claim 3, wherein hot-rolled processing parameters of the said cold-rolled electromagnetic pure iron sheet strip are: heating temperature of 1000∼1200°C; final rolling temperature of 750∼900°C; reeling temperature of 550∼720°C; cold-rolled reduction rate of within 30∼55%.
 





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Cited references

REFERENCES CITED IN THE DESCRIPTION



This list of references cited by the applicant is for the reader's convenience only. It does not form part of the European patent document. Even though great care has been taken in compiling the references, errors or omissions cannot be excluded and the EPO disclaims all liability in this regard.

Patent documents cited in the description