阅读说明：本技术 一种实验室低温高磁感取向硅钢热轧钢带及其制备方法 (Laboratory low-temperature high-magnetic-induction oriented silicon steel hot-rolled steel strip and preparation method thereof ) 是由 卢晓禹 王少炳 刘朋成 黄利 杨雄 樊立峰 魏淼 董丽丽 王海明 于 2020-05-07 设计创作，主要内容包括：本发明公开了一种实验室低温高磁感取向硅钢热轧钢带及其制备方法,本发明提供的热轧钢带的化学成分按质量百分比计为：C：0.02～0.04％,Si：3.00～3.25％,Mn：0.10～0.20％,P：0.015～0.030％,S：0.006～0.008％,Als：0.022～0.029％,Cu：0.45～0.55％,N：0.0070～0.0110％,Cr：0.10～0.14％,O：≤0.0030％,其余为Fe及不可避免的杂质。该热轧钢带的制备方法采用加热-粗轧-再加热-精轧的轧制模式,由获得的热轧钢带制成的成品钢具有优异的低温高磁感特点。(The invention discloses a laboratory low-temperature high-magnetic-induction oriented silicon steel hot-rolled steel strip and a preparation method thereof, and the hot-rolled steel strip provided by the invention comprises the following chemical components in percentage by mass: c: 0.02 to 0.04%, Si: 3.00-3.25%, Mn: 0.10-0.20%, P: 0.015-0.030%, S: 0.006-0.008%, Als: 0.022-0.029%, Cu: 0.45-0.55%, N: 0.0070-0.0110%, Cr: 0.10-0.14%, O: less than or equal to 0.0030 percent, and the balance of Fe and inevitable impurities. The preparation method of the hot rolled steel strip adopts a rolling mode of heating, rough rolling, reheating and finish rolling, and finished steel made of the obtained hot rolled steel strip has the characteristics of excellent low-temperature high magnetic induction.)

1. The laboratory low-temperature high-magnetic-induction oriented silicon steel hot-rolled steel strip is characterized by comprising the following chemical components in percentage by mass: c: 0.02 to 0.04%, Si: 3.00-3.25%, Mn: 0.10-0.20%, P: 0.015-0.030%, S: 0.006-0.008%, Als: 0.022-0.029%, Cu: 0.45-0.55%, N: 0.0070-0.0110%, Cr: 0.10-0.14%, O: less than or equal to 0.0030 percent, and the balance of Fe and inevitable impurities.

2. The hot rolled steel strip as claimed in claim 1 having mechanical properties satisfying: the yield strength is more than or equal to 603MPa, the tensile strength is more than or equal to 658MPa, the elongation A is more than or equal to 23.5 percent, and the metallographic structure is ferrite and pearlite.

3. The method of producing a hot-rolled steel strip according to claim 1 or 2, comprising a smelting and hot-rolling process, wherein a 25kg vacuum electric furnace is used for smelting to produce a conical steel ingot having a maximum diameter of 110 mm.

4. The method as claimed in claim 3, wherein the hot rolling procedure adopts a 750mm x 550mm high-rigidity two-roller hot rolling experimental rolling mill for rolling, and the rolled steel plate is placed into a simulated coiling furnace for heat preservation and slow cooling to room temperature; wherein, the hot rolling process adopts a rolling mode of heating-rough rolling-reheating-finish rolling to heat the conical steel ingot to a target temperature for rough rolling, the steel plate is cut into two after the rough rolling is finished, the steel plate is put into a heating furnace to be reheated to a temperature higher than the finish rolling initial rolling temperature, and then finish rolling is carried out, wherein:

the target temperature for heating the conical steel ingot is 1190 +/-10 ℃, and the heating time is more than 240 min;

the initial rolling temperature of rough rolling is 1150 +/-10 ℃;

cutting the steel plate into two parts, heating to 1150 +/-20 ℃, and heating for less than 30 min;

the starting temperature of finish rolling is 1100 +/-10 ℃;

the finish rolling temperature is 950 +/-15 ℃;

the coiling temperature is 550 +/-15 ℃.

Technical Field

The invention belongs to the technical field of oriented silicon steel preparation, and particularly relates to a laboratory low-temperature high-magnetic-induction oriented silicon steel hot-rolled steel strip and a preparation method thereof.

Background

Silicon steel is an important soft magnetic alloy indispensable to the power, electronic and military industries, and is mainly used as iron cores of various motors, generators and transformers. The production process is complex, the manufacturing technology is strict, and the product is regarded as the life of an enterprise.

Document CN107858494B discloses a method for producing low-temperature high-magnetic induction oriented silicon steel. The key point is to introduce the normalization of pickling and the control of the subsequent processes, so as to obtain the low-temperature high-magnetic induction oriented silicon steel with small iron loss fluctuation, but the method provided by the document is not suitable for the production under the limited conditions of a laboratory.

Document CN109112283A discloses a preparation method of low-temperature high-magnetic-induction oriented silicon steel. The action and control of various inhibitors are mainly introduced, the normalizing step is omitted, the flow is simplified, and the low-temperature oriented silicon steel with low cost is obtained, but the temperature in the preparation process is high, the heating furnace is damaged, more inhibitors are used, the cost is increased, and the smelting of molten steel is not facilitated.

Document CN109136503A discloses a preparation method of low-temperature high-magnetic-induction oriented silicon steel. The method mainly introduces the adoption of a rapid heating technology, calculates the conditions such as decarburization annealing time and the like according to the heating rate, controls the size and the uniformity of primary crystallization, and further improves the magnetic property of a product.

Disclosure of Invention

In order to solve one or more problems in the prior art, one aspect of the invention provides a laboratory low-temperature high-magnetic-induction oriented silicon steel hot-rolled steel strip, which comprises the following chemical components in percentage by mass: c: 0.02 to 0.04%, Si: 3.00-3.25%, Mn: 0.10-0.20%, P: 0.015-0.030%, S: 0.006-0.008%, Als: 0.022-0.029%, Cu: 0.45-0.55%, N: 0.0070-0.0110%, Cr: 0.10-0.14%, O: less than or equal to 0.0030 percent, and the balance of Fe and inevitable impurities.

The mechanical properties of the hot-rolled steel strip meet the following requirements: the yield strength is more than or equal to 603MPa, the tensile strength is more than or equal to 658MPa, the elongation A is more than or equal to 23.5 percent, and the metallographic structure is ferrite and pearlite.

The invention also provides a preparation method of the hot rolled steel strip, which comprises smelting and hot rolling processes, wherein in the smelting process, a 25kg vacuum electric furnace is adopted for smelting, and conical steel ingots with the maximum diameter of 110mm are manufactured.

In the method, the hot rolling procedure adopts a high-rigidity two-roller hot rolling experimental rolling mill with the thickness of 750mm multiplied by 550mm for rolling, and the rolled steel plate is put into a simulated coiling furnace for heat preservation and is slowly cooled to the room temperature; wherein, the hot rolling process adopts a rolling mode of heating-rough rolling-reheating-finish rolling to heat the conical steel ingot to a target temperature for rough rolling, the steel plate is cut into two after the rough rolling is finished, the steel plate is put into a heating furnace to be reheated to a temperature higher than the finish rolling initial rolling temperature, and then finish rolling is carried out, wherein:

the target temperature for heating the conical steel ingot is 1190 +/-10 ℃, and the heating time is more than 240 min;

the initial rolling temperature of rough rolling is 1150 +/-10 ℃;

cutting the steel plate into two parts, heating to 1150 +/-20 ℃, and heating for less than 30 min;

the starting temperature of finish rolling is 1100 +/-10 ℃;

the finish rolling temperature is 950 +/-15 ℃;

the coiling temperature is 550 +/-15 ℃.

The preparation method of the laboratory low-temperature high-magnetic induction oriented silicon steel hot rolled steel strip based on the technical scheme only adopts AlN and MnS as main inhibitors to carry out component design, thereby greatly reducing the use of the inhibitors, being beneficial to molten steel smelting and cost reduction, and being lower in heating temperature in the preparation process and being beneficial to protecting equipment such as a heating furnace and the like; and a rolling mode of heating, rough rolling, reheating and finish rolling is set according to the specific conditions of a laboratory, so that a hot rolling structure of the low-temperature high-magnetic-induction oriented silicon steel is successfully obtained, a good foundation is laid for the subsequent normalizing, cold rolling and annealing processes, technical support can be provided for industrial trial production, and the process adjustment times in the industrial trial production process are reduced.

Drawings

FIG. 1 is a metallographic structure photograph of a hot-rolled steel strip obtained in example 1.

FIG. 2 is a graph showing the iron loss curve of the experimental steel obtained in example 3.

Fig. 3 is a magnetization curve of the experimental steel obtained in example 3.

Detailed Description

The invention aims to provide a laboratory low-temperature high-magnetic-induction oriented silicon steel hot-rolled steel strip and a preparation method thereof, which are used for providing technical support for industrial trial production and reducing the process adjustment times in the industrial trial production process.

The preparation method provided by the method mainly comprises the following steps:

(1) in the smelting process, a 25kg vacuum electric furnace is adopted for smelting to manufacture conical steel ingots with the maximum diameter of 110 mm;

(2) in the hot rolling procedure, a 750mm multiplied by 550mm high-rigidity two-roller hot rolling experimental rolling mill is used for rolling, and the rolled steel plate is placed into a simulated coiling furnace for heat preservation and is slowly cooled to room temperature. Because the laboratory sample is small and the heat dissipation is fast, in order to ensure the temperature control in the rolling process, a brand new rolling mode in the laboratory, namely a heating-rough rolling-reheating-finish rolling mode, is adopted. Heating the conical steel ingot with the maximum diameter of 110mm to a target temperature, carrying out rough rolling, cutting the steel plate into two pieces after the rough rolling is finished, putting the steel plate into a heating furnace, reheating the steel plate to a temperature above the finish rolling starting temperature, and carrying out finish rolling to obtain a hot rolled steel strip. Wherein: the target temperature for heating the conical steel ingot is 1190 +/-10 ℃, and the heating time is more than 240 min; the initial rolling temperature of rough rolling is 1150 +/-10 ℃; cutting the steel plate into two parts, heating to 1150 +/-20 ℃, and heating for less than 30 min; the starting temperature of finish rolling is 1100 +/-10 ℃; the finish rolling temperature is 950 +/-15 ℃; the coiling temperature is 550 +/-15 ℃.

In the rolling mode of heating-rough rolling-reheating-finish rolling, the inventors found that the reheating time cannot be too long, and the reheating temperature cannot be too high, which would otherwise result in excessively large grains, resulting in a significant decrease in the magnetic properties of the final product; in the invention, the reheating time is less than 30min, and the finish rolling is carried out after the reheating is carried out to 1150 ℃, so that the stability and the sufficient reduction rate of the finish rolling can be ensured, and the precipitation of an inhibitor is facilitated. The reheating temperature reaches 1150 ℃, then the finish rolling is carried out, the MnS precipitation peak temperature of the inhibitor can be ensured, a large amount of dislocation generated in the finish rolling process can promote the MnS to be dispersed more quickly and uniformly, and the improvement of the magnetic property is facilitated; the temperature of 1000 ℃ is a sulfide precipitation peak value of copper, and the dispersed copper, manganese and sulfur compound can be used as a core of AlN precipitation during normalization, so that the inhibitor AlN is favorably dispersed and precipitated in a fine manner, and the magnetism is good and stable.

The present invention will be described in detail below by way of examples, which are merely illustrative of the best mode for carrying out the present invention and do not limit the present invention in any way.

The chemical composition contents of each example are shown in Table 1.

Table 1: chemical composition (wt%) of smelting