Preparation of 6.5%Si High Silicon Steel by Pack Rolling Method and its Performance Characteristics

doi:10.20057/j.1003-8620.2023-00032

Special Steel ›› 2023, Vol. 44 ›› Issue (4): 114-119.DOI: 10.20057/j.1003-8620.2023-00032

• Forming and Phase Transition • Previous Articles Next Articles

Preparation of 6.5%Si High Silicon Steel by Pack Rolling Method and its Performance Characteristics

Chen　Jinqi¹， Cheng　Zhaoyang¹， Feng　Dajun¹， Wang　Xiaoxiao¹， Shi　Xiangju²， Peng　Zhixian^1，3

1 The State Key Laboratory of Refractories and Metallurgy， Wuhan University of Science and Technology， Wuhan 430081，China；
2 Putian Low-Carbon Industry Research Institute， Wuxi Putian Iron Core Co.， Ltd.， Wuxi 214192，China；
3 Scientific Research Department， Zhejiang Jincheng New Material Co.， Ltd.， Huzhou 313100， China

Received:2023-03-03 Online:2023-08-01 Published:2023-07-14

包套轧制法制备6.5%Si高硅钢及其性能特点

陈锦旗¹，程朝阳¹，冯大军¹，王小小¹，石祥聚²，彭志贤^1，3

1 武汉科技大学省部共建耐火材料与冶金国家重点实验室，武汉430081；
2 无锡普天铁心股份有限公司普天低碳产业研究院，无锡214192；
3 浙江锦诚新材料股份有限公司科研部，湖州313100

通讯作者: 石祥聚
作者简介:陈锦旗（2002-），男，本科
基金资助:
国家自然科学基金（No.52274393，No.51804231），湖北省自然科学基金（No.2022CFB091）,校级大学生创新创业训练计划项目（22Z007）

Abstract

Abstract: In view of the brittleness and difficulty in rolling of 6.5% Si high silicon steel at room temperature， ordinary silicon steel hot rolled plate （≤3%Si） is used to cover the high silicon steel （6%-8%Si） billet，and produce 0.3 mm thickness high silicon steel strip by hot rolling， warm rolling and high temperature annealing. It is found that the hot-rolled high silicon steel by pack rolling has a brittle-ductile transition in the range of room temperature and 280 ℃， the elongation increases significantly at 280 ℃， and the fracture morphology exhibits a large number of toughness nests， manifested as plastic fracture. According to the real-time monitoring of the process parameters， it can be seen that the average rolling force of the pack-hot-rolled 6.5% high silicon steel during warm rolling at 550-600 ℃ is related to the plate thickness， roller gap， material hardening degree， rolling temperature and other factors. The reduction rate first increases and then decreases with the thickness reduction. The reason for the reduction is related to the saturation of rolling load and the proximity of rolling thickness to the target thickness. The ratio of the cladding layer to the core layer of the warm-rolled-finished plate is 1/5， 0.3 mm thick warm-rolled plate after annealing at high temperature， the high-frequency iron loss P_0.2/10k of finished plate is 78.8 W/kg， presenting excellent magnetic properties， which is significantly lower than that of the ordinary silicon steel with 3% Si.

Key words: 6.5%Si High Silicon Steel, Pack Rolling, Mechanical Properties, Magnetic Properties

摘要： 本文针对6.5%Si高硅钢的室温脆性难以轧制问题，采用普通硅钢热轧板（≤3%Si）对高硅钢（6%～8%Si）钢坯进行包套，通过热轧、温轧及高温退火制备0.3 mm厚高硅钢带材。通过研究发现，包套高硅钢热轧板在室温和280 ℃温度区间发生了较为明显的脆性-韧性转变，在280 ℃拉伸时延伸率显著增大，断口形貌呈现出大量韧窝，表现为塑性断裂。根据实时监测的工艺参数可知，包套6.5%Si高硅钢热轧板在550～600 ℃温轧时的平均轧制力与板厚、辊缝、材料硬化程度及开轧温度等因素相关，压下率随着厚度的减薄先增大而后减小，减小的原因与轧制负荷趋于饱和及轧制厚度接近目标厚度有关。温轧成品板的包覆层与中间层之比为1/5，0.3 mm厚温轧板经高温退火后，制备出成品板磁性能优异，其高频铁损P_0.2/10k为78.8 W/kg，明显低于普通的3%Si硅钢。

关键词: 6.5%Si高硅钢, 包套轧制, 力学性能, 磁性能

CLC Number:

TG132.2

Chen　Jinqi, Cheng　Zhaoyang, Feng　Dajun, Wang　Xiaoxiao, Shi　Xiangju, Peng　Zhixian. Preparation of 6.5%Si High Silicon Steel by Pack Rolling Method and its Performance Characteristics[J]. Special Steel, 2023, 44(4): 114-119.

陈锦旗, 程朝阳, 冯大军, 王小小, 石祥聚, 彭志贤. 包套轧制法制备6.5%Si高硅钢及其性能特点[J]. 特殊钢, 2023, 44(4): 114-119.

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Preparation of 6.5%Si High Silicon Steel by Pack Rolling Method and its Performance Characteristics

包套轧制法制备6.5%Si高硅钢及其性能特点

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