S. Dorofeev, A. Voynov, A. Goncharov, N. Slavinskaya, K. Doroshenko
{"title":"RESEARCH OF MELT PROCESSING IMPACT WITH ELECTROMAGNETIC PULSES UPON SILUMIN WEAR-RESISTANCE","authors":"S. Dorofeev, A. Voynov, A. Goncharov, N. Slavinskaya, K. Doroshenko","doi":"10.30987/1999-8775-2021-4-28-35","DOIUrl":null,"url":null,"abstract":"To improve functional properties of pre-eutectic silumins there are used many different methods having a complex effect upon processes of structure formation and physical-mechanical properties of alloys. \nIn this paper there is offered a method for alloy operation characteristics increase by the example of wear-resistance by the impact of nanosecond electro-magnetic pulses (NEMP) upon silumin melt AK7ch (AL9). \nMelt illumination was carried out with the generator (NEMP) (GNI-01-1-6) submersible rod radiator. The melt was overheated to 900ºC and processed with NEMP with the length up to 25 min after that it was cooled at a rate of 20ºC/min. Slow cooling contributed to the formation of a structure close to equilibrium. Cylindrical ingots with a diameter of 0.06 m (60mm) and a height of 0.06 m (60 mm) were obtained. Wear-resistance was defined on a cross cut of ingots according to GOST 23.208-79. As a standard of comparison were used non-irradiated samples of silumin. \nIt is defined that melt NEMP processing changes considerably parameters of crystallization, structure formation and increases silumin properties. At abrasive wear, silumin wear-resistance changes from the duration of melt electro-pulse processing according to an extreme dependence with the evident maximum at melt irradiation in the course of 15 min. At that in the edge area of the ingot wear-resistance increases by 1.54 times, and in the central one – by 1.34 times. \nThis effect is explained by the fact that during melt NEMP processing during 15 min the characteristics of alloy micro-structure change considerably: morphology and dimensions of structural constituents. At that there is formed a qualitatively new fine structure of a non-dendritic type which ensures maximum values of alloy wear-resistance. The data obtained allow developing technology of wear-resistant silumin fusion intended for operation under abrasive wear conditions.","PeriodicalId":9358,"journal":{"name":"Bulletin of Bryansk state technical university","volume":"15 1","pages":"28-35"},"PeriodicalIF":0.0000,"publicationDate":"2021-04-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Bulletin of Bryansk state technical university","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.30987/1999-8775-2021-4-28-35","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
To improve functional properties of pre-eutectic silumins there are used many different methods having a complex effect upon processes of structure formation and physical-mechanical properties of alloys.
In this paper there is offered a method for alloy operation characteristics increase by the example of wear-resistance by the impact of nanosecond electro-magnetic pulses (NEMP) upon silumin melt AK7ch (AL9).
Melt illumination was carried out with the generator (NEMP) (GNI-01-1-6) submersible rod radiator. The melt was overheated to 900ºC and processed with NEMP with the length up to 25 min after that it was cooled at a rate of 20ºC/min. Slow cooling contributed to the formation of a structure close to equilibrium. Cylindrical ingots with a diameter of 0.06 m (60mm) and a height of 0.06 m (60 mm) were obtained. Wear-resistance was defined on a cross cut of ingots according to GOST 23.208-79. As a standard of comparison were used non-irradiated samples of silumin.
It is defined that melt NEMP processing changes considerably parameters of crystallization, structure formation and increases silumin properties. At abrasive wear, silumin wear-resistance changes from the duration of melt electro-pulse processing according to an extreme dependence with the evident maximum at melt irradiation in the course of 15 min. At that in the edge area of the ingot wear-resistance increases by 1.54 times, and in the central one – by 1.34 times.
This effect is explained by the fact that during melt NEMP processing during 15 min the characteristics of alloy micro-structure change considerably: morphology and dimensions of structural constituents. At that there is formed a qualitatively new fine structure of a non-dendritic type which ensures maximum values of alloy wear-resistance. The data obtained allow developing technology of wear-resistant silumin fusion intended for operation under abrasive wear conditions.
为了提高预共晶硅明的功能性能,采用了许多不同的方法,这些方法对合金的组织形成过程和物理力学性能有复杂的影响。本文以纳秒级电磁脉冲(NEMP)对硅敏熔体AK7ch (AL9)的耐磨性影响为例,提出了一种提高合金工作特性的方法。采用发电机(NEMP) (GNI-01-1-6)潜水棒散热器进行熔体照明。将熔体过热至900ºC,用NEMP处理,长度可达25分钟,然后以20ºC/min的速度冷却。缓慢冷却有助于形成接近平衡的结构。得到了直径为0.06 m (60mm),高度为0.06 m (60mm)的圆柱锭。根据GOST 23.208-79在钢锭的横切上定义耐磨性。采用未辐照的矽明样品作为对照标准。研究表明,熔体NEMP工艺能显著改变晶化、结构形成等参数,提高硅质性能。在磨粒磨损时,硅明的耐磨性随熔体电脉冲处理时间的变化呈极依赖关系,在熔体辐照15 min时达到明显的最大值。在钢锭边缘区域耐磨性增加了1.54倍,在中心区域耐磨性增加了1.34倍。这种影响可以用以下事实来解释:在熔体NEMP处理的15分钟内,合金的微观组织特征发生了很大的变化:组织成分的形貌和尺寸。在此基础上形成了一种新的非枝晶型精细组织,保证了合金的最大耐磨性。所获得的数据允许开发用于磨料磨损条件下操作的耐磨硅敏熔合技术。