Optimization Design and Production Practice for Increasing Rolling Yield of Die Steel 3.1 t Ingot

doi:10.20057/j.1003-8620.2022-00123

Abstract

Abstract: Yield rate is an important factor to be considered in the production of rolled ingot for die steel. The redesigns and optimizes of the original 3.0 t die steel ingot used in a steel plant are carried out by using Procast simulation software to simulate the temperature field， total setting time and internal defects during the solidification process， aiming to improve the yield rate under the premise of ensuring quality. The results showed that the total solidification time of new designed 3.1 t ingot is 1.78 h， and that of original 3.0 t ingot is 2.03 h， the total solidification time is reduced by 12.32%， and the ingot internal quality is good. On the premise of covering the existing rolling specifications and without increasing the rolling passes， the number of ingots is reduced from 5 to 4. The newly designed 3.1 t steel ingot is produced in small batch by using 40 t EAF-LF-VD die casting process. After initial rolling， it qualified the GB /T4162-2008 grade B flaw detection specification. The average yield rate of the optimized ingot is 83.76%， the average yield rate of the original ingot is 78.71%， and the average yield rate is 5.05% higher than the original.

Key words: Yield Rate, Die Steel, Ingot Optimization Design, Numerical Simulation

摘要： 成材率是模具钢用轧制锭生产中需要考虑的重要因素。对钢厂原有3.0 t模具钢用轧制锭进行重新设计与优化，并使用Procast模拟软件对其凝固过程的温度场、全凝时间和内部缺陷进行了模拟计算，旨在保证质量的前提下提高成材率。研究结果表明，新设计3.1 t钢锭的全凝时间为1.78 h，原有3.0 t锭型全凝时间为2.03 h，全凝时间缩短了12.32%，钢锭内部质量良好。在涵盖现有轧制规格和不增加轧制道次的前提下，锭型数量由5个减少到4个。采用40 t EAF-LF-VD模铸工艺路线对新设计的3.1 t钢锭进行小批量生产，初轧后满足GB/T4162-2008 B级探伤规格。锭型优化后的的平均成材率为83.76%，原锭型的平均成材率为78.71%，平均成材率比原来提高5.05%。

关键词: 成材率, 模具钢, 钢锭优化设计, 数值模拟

Han　Dong. Optimization Design and Production Practice for Increasing Rolling Yield of Die Steel 3.1 t Ingot[J]. Special Steel, 2023, 44(3): 14-19.

韩东. 提高模具钢3.1 t锭轧制成材率的优化设计与生产实践[J]. 特殊钢, 2023, 44(3): 14-19.

References

［1］梁新腾，谢珍勇，孙彦辉，等. 冷作模具钢Cr12MoV 40 t EAF-LF-VD-模铸冶炼工艺优化实践［J］. 特殊钢， 2017， 38（4）： 32-34.
［2］ CHEN， ChengShun， HUANG. Experimental Study on Five-Axis Machining Parameter for NAK80 die steel［J］. Materials Science Forum， 2008， 594：226-234.
［3］ He S， Li C， Han Y. Evolution of the Microstructure and Hardness of Fe-8Cr-2.1Mo-Si-V Die Steel at Different Cooling Rates after Hot Deformation［J］. Journal of Materials Engineering and Performance， 2019， 28（5）.
［4］ Zhou Z C ， Du J ， Yan Y J ， et al. The Recent Development of Study on H13 Hot-Work Die Steel［J］. Solid State Phenomena， 2018， 8（17）： 55-59.
［5］ Sun F， Zhang D Q， Cheng L， et al. Microstructure Evolution Modeling and Simulation for Dynamic Recrystallization of Cr12MoV Die Steel During Hot Compression Based on Real Metallographic Image［J］. Metals and Materials International， 2019， 2（7）： 1-16.
［6］刘宏伟，栾义坤，傅排先，等. 优质模铸钢锭制备工艺研究［J］. 炼钢， 2016， 32（4）： 44-48.
［7］ Tkadleckova M ， Jonsta P ， Carbol Z ， et al. Distribution of porosity and macrosegregation in slab steel ingot［J］. IOP Conference Series： Materials Science and Engineering， 2017， 179： 012067.
［8］ Houfa S， Kangxin C， Baicheng L. Numerical Simulation of Macrosegregation in Steel Ingot Casting［J］. Acta Metallurgica Sinica， 2018.
［9］李硕，穆科宇，邸楠. 5CrMnMo模具断裂分析［J］. 金属加工（热加工）， 2016（21）：43-44.
［10］ Zhen-Tian L ， Jian Z ， Dang-Shen M A ， et al. Defect analysis of central cavity for A2 cold work die steel［J］. Physics Examination and Testing， 2015（3）： 5
［11］关锐. 高成材率模具钢用轧制锭的优化设计及生产实践［J］. 轧钢， 2016， 33（2）：42-45.
［12］胡林. 钢锭设计原理［M］. 北京：冶金工业出版社， 2015.
［13］陈晋阳.钢锭锭型与锭模设计中的关键参数探析［J］.特钢技术，2016，22（3）：1-4+13.
［14］ Tashiro K， Watanabe S， Kitagawa I， et al. Influence of Mould Design on the Solidification and Soundness of Heavy Forging Ingots［J］. Transactions of the Iron and Steel Institute of Japan， 2006， 23（4）： 312-321.
［15］郭栋. 钢锭帽容比优化成材率影响的质量验证［J］. 科技风， 2018， 9（25）：154.
［16］赵亚楠，卜恒勇，郭建政，等.锥度及高径比对大型钢锭质量的影响［J］.大型铸锻件，2017（5）：27-31+62.
［17］赵岽，吴庆君. 德国DIN标准热作模具钢X40CrMoV5-1在热矫直辊材料中的应用［J］. 中国重型装备， 2012， 6（2）：27-29.

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