电子束熔炼功率对GH4068合金微观组织、偏析和 γ′相析出行为的影响

doi:10.11900/0412.1961.2023.00263

金属学报

2024, Vol. 60

Issue (9): 1189-1199 DOI: 10.11900/0412.1961.2023.00263

研究论文

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电子束熔炼功率对GH4068合金微观组织、偏析和 γ′相析出行为的影响

白如圣¹^,², 谭毅¹^,²(

), 崔弘阳¹^,², 宁莉丹¹^,², 崔传勇³, 王云鹏¹, 李鹏廷¹^,²

^1.大连理工大学材料科学与工程学院大连 116024
^2.大连理工大学辽宁省载能束冶金及先进材料制备重点实验室大连 116024
^3.中国科学院金属研究所师昌绪先进材料创新中心沈阳 110016

Effect of Electron Beam Smelting Power on Microstructure, Segregation, and γ′ Phase Precipitation Behavior of GH4068 Alloy

BAI Rusheng¹^,², TAN Yi¹^,²(

), CUI Hongyang¹^,², NING Lidan¹^,², CUI Chuanyong³, WANG Yunpeng¹, LI Pengting¹^,²

^1.School of Materials Science and Engineering, Dalian University of Technology, Dalian 116024, China
^2.Key Laboratory For Energy Beam Metallurgy and Advanced Materials Preparation of Liaoning Province, Dalian University of Technology, Dalian 116024, China
^3.Shi -changxu Innovation Center for Advanced Materials, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China

引用本文:

白如圣, 谭毅, 崔弘阳, 宁莉丹, 崔传勇, 王云鹏, 李鹏廷. 电子束熔炼功率对GH4068合金微观组织、偏析和 γ′相析出行为的影响[J]. 金属学报, 2024, 60(9): 1189-1199.
Rusheng BAI, Yi TAN, Hongyang CUI, Lidan NING, Chuanyong CUI, Yunpeng WANG, Pengting LI. Effect of Electron Beam Smelting Power on Microstructure, Segregation, and γ′ Phase Precipitation Behavior of GH4068 Alloy[J]. Acta Metall Sin, 2024, 60(9): 1189-1199.

全文: PDF(3919 KB) HTML

摘要:

高合金化的变形高温合金铸态组织存在微观偏析较大、组织均匀性差等问题，严重影响了其后续热加工性能。为了优化变形高温合金的铸态组织，采用电子束熔炼(EBS)法熔炼GH4068合金，采用不同EBS功率熔炼10 min制备低偏析的GH4068合金铸锭。结果表明：经过EBS熔炼后的铸锭底部为细晶区，仅存在胞状偏析和胞状树枝晶，中部较大区域为竖直生长的柱状晶区，二次枝晶生长方向与柱状晶生长方向平行，顶部存在少量等轴晶，枝晶生长方向较为杂乱。成分分析表明，合金中Cr元素挥发最为明显，当EBS功率为17 kW时，其含量降低1.97%。EBS较传统真空感应熔炼(VIM) +电渣重熔熔炼(ESR)双联工艺所制备的铸锭组织更为均匀，当EBS功率为12 kW时，二次枝晶间距λ₂为44.6 μm，与双联工艺相比，λ₂减小了32.2%，铸锭枝晶区微观偏析程度明显降低，典型易偏析元素Ti和W的微观偏析程度分别降低了20.4%和18.6%。枝晶间γ′相尺寸较大、呈块状析出，而枝晶干的γ′相呈球状且尺寸较枝晶间更为均匀细小，在EBS功率为12 kW时所制备铸锭的γ′相尺寸最小且枝晶间不规则γ′相最少。在EBS过程中，熔体的实际温度远高于合金的熔化温度，熔体经过过热处理后团簇结构有效分解，元素分布更为均匀，在凝固过程中过冷度增加，熔体的均匀性遗传到凝固组织中使铸态组织细化，微观偏析程度降低。同时，在EBS过程中，由于电子束在熔池表面的轰击产生局部高温，能够有效降低合金中的N含量。

关键词 ：电子束熔炼, 高温合金, 枝晶组织, 微观偏析

Abstract：

The as-cast structure of high-alloyed wrought superalloys exhibits disadvantages such as high microscopic segregation and poor microstructure uniformity, severely affecting their subsequent hot working and deformation properties. To optimize the as-cast structure of the wrought superalloy, GH4068 alloy was smelted via electron beam smelting (EBS), and its ingots with low segregation were prepared by setting different EBS powers for 10 min. The results show that the bottom of the ingots after EBS appeared to be fine grain regions, with the presence of only cellular segregation structure and cellular dendritic crystal; the large area in the middle became vertically growing columnar crystal regions, the direction of secondary dendrite crystal growth was parallel to that of the columnar crystal growth; a small amount of equiaxed crystal was observed at the top, and the growth direction of dendritic crystals was disordered. Analyzing the compositions of ingots revealed that Cr volatilization in this alloy was the most obvious; the Cr content decreased by 1.97% when the EBS power was 17 kW. The ingot structure prepared via EBS was more highly distributed than that obtained using the traditional vacuum induction melting + electroslag remelting duplex process. When the EBS power was 12 kW, the secondary dendrite spacing λ₂ was 44.6 μm, which was 32.2% less than that yielded using the duplex process, the degree of the microscopic segregation of the ingot dendrite region decreased considerably, and the degree of the microscopic segregation of the typical easily segregated elements Ti and W reduced by 20.4% and 18.6%, respectively. Furthermore, the massive precipitation of large interdendritic γ′ phases were observed, while the γ′ phases in the dendritic core were spherical and smaller in size than those in the interdendritic. Meanwhile, the ingot prepared with an EBS power of 12 kW achieved the smallest size for γ′ phases and least irregular γ′ phases in the interdendritic. In the EBS process, the actual melt temperature was considerably higher than the alloy melting temperature. After the overheating of the melt, the cluster structure effectively decomposed, elements were uniformly distributed, the degree of subcooling increased in the solidification process, and the uniformity of the melt was inherited to the solidification structure to refine the as-cast structure and reduce the degree of microscopic segregation. Meanwhile, during the EBS process, local high temperature generated due to the electron beam bombardment on the surface of the molten pool effectively reduced the N content in the alloy.

Key words： electron beam smelting superalloy dendritic structure microscopic segregation

收稿日期: 2023-06-19

ZTFLH:

TF19

基金资助:国家重点研发计划项目(2019YFA0705300)

通讯作者: 谭毅，lnsolar@dlut.edu.cn，主要从事载能束冶金制备高温合金的研究

Corresponding author: TAN Yi, professor, Tel: (0411)84707583, E-mail: lnsolar@dlut.edu.cn

作者简介: 白如圣，男，1998年生，博士生

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https://www.ams.org.cn/CN/10.11900/0412.1961.2023.00263 或 https://www.ams.org.cn/CN/Y2024/V60/I9/1189

图1 SEBM-30A型电子束熔炼(EBS)装备示意图

图2 GH4068合金的DSC升温曲线

图3 EBS工艺为12 kW、10 min时GH4068合金铸锭的宏观相貌

图4 不同EBS功率熔炼10 min制备的GH4068合金铸锭的质量损失和质量损失率

表1 不同EBS功率熔炼10 min 制备的GH4068合金铸锭中各元素含量相对于原料的变化量 (mass fraction / %)

图5 EBS工艺为12 kW、10 min时GH4068铸锭中心区域晶粒和枝晶结构的OM像

图6 温度梯度(G)和凝固速率(R)随凝固时间的变化曲线及G /R和合金成分(ω0)对合金晶粒生长形貌的影响

图7 双联工艺[14]和不同EBS功率熔炼10 min制备的GH4068合金铸锭的二次枝晶间距(λ2)和冷却速率

图8 过热温度、形核过冷度与团簇结构变化的关系示意图

图9 EBS工艺为12 kW、10 min时制备的GH4068合金铸锭枝晶组织的背散射电子(BSE)-SEM像和EPMA元素面扫描分布图

图10 双联工艺[14]和不同EBS功率熔炼10 min制备的GH4068合金铸锭元素的微观偏析系数

图11 不同EBS功率熔炼10 min制备的GH4068合金铸锭中γ′相在枝晶干析出的SEM像

图12 不同EBS功率熔炼10 min制备的GH4068合金铸锭中γ′相在枝晶间析出的SEM像

图13 不同EBS功率熔炼10 min制备的GH4068合金铸锭枝晶干和枝晶间γ′相的平均尺寸

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