泡沫铝夹芯板粉末冶金发泡机理的SR-CT研究

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英文篇名：Study on Powder Metallurgical Foaming Mechanism of Aluminum Foam Sandwich Using SR-CT 作者：祖国胤 ; 孙溪 ; 黄鹏 ; 孙世亮 英文作者：Zu Guoyin;Sun Xi;Huang Peng;Sun Shiliang;Northeastern University; 关键词：泡沫铝夹芯板 ; SR-CT ; 粉末冶金 ; 发泡机理 ; 孔隙率 英文关键词：aluminum foam sandwich;;SR-CT;;powder metallurgy;;foaming mechanism;;porosity 中文刊名：COSE 英文刊名：Rare Metal Materials and Engineering 机构：东北大学; 出版日期：2017-10-15 出版单位：稀有金属材料与工程 年：2017 期：v.46;No.375 基金：国家自然科学基金(U1332110);; 辽宁省“百千万人才工程”项目(2013921071);; 中央高校基本科研业务费(N140204003) 语种：中文; 页：COSE201710066 页数：5 CN：10 ISSN：61-1154/TG 分类号：393-397

摘要

利用同步辐射装置的SR-CT,通过图像的断层扫描及3D重建,对轧制复合-粉末冶金发泡工艺制备的泡沫铝夹芯板(AFS)进行了泡孔结构演化的研究,分析了发泡过程中孔隙率的变化及大尺寸连通孔的形成原因。研究结果表明:具有微米级空间分辨率的SR-CT可清晰地观测到泡孔萌生及生长各阶段的泡沫结构。泡孔在发泡15~30 s阶段生成,形状为垂直于轧制方向的类裂纹孔。发泡45 s时,泡孔开始发生明显合并,继续延长发泡时间易导致形成大尺寸连通孔。芯层泡沫铝的孔隙率在泡孔的萌生阶段及合并阶段增长幅度较大,减少混料时发泡剂的"团聚"及提高芯层粉末致密度可获得良好的芯层泡沫结构。
        The research of cellular structure evolution of aluminum foam sandwich(AFS) made by the pack rolling/powder metallurgy foaming process has been done using SR-CT, and the variation of porosity of aluminum foam and formation of oversized connected pores have been analyzed. The results show that the cellular structure can be observed clearly during the appearing and growing stages by SR-CT with the spatial resolution of micrometer. The bubble hole similar to spalttupfel which is perpendicular to the rolling direction is generated between 15 s and 30 s, and then there is an obvious merging at about 45 s. With time going on, the oversized connected hole forms more easily. The porosity of aluminum foam increases quickly at the stage of appearing and merging process. So in order to gain excellent foaming structure of sandwich layer, the reduction of the reunion of foaming agent during mixing material and improvement of powder relative density of the sandwich layer is necessary.

引文

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