从cu-sic金属基复合材料中获得用于节能导热系统的大块产品

IF 0.6 Q4 ENGINEERING, GEOLOGICAL
D. Nikitin, I. Shanenkov, Artur Nassyrbayev, Y. Vympina, E. Orlova, A. Ivashutenko, A. Sivkov
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引用次数: 0

摘要

引用链接:Nikitin D.S, Shanenkov I.I, nassybayev A, vynpina Yu。N., Orlova, Ivashutenko a.s., Sivkov A.A.。从Cu-SiC金属基复合材料中获得节能导热系统的批量产品。托木斯克理工大学公报。岩土工程Аssets, 2023,第334卷,第2期。7,рр。93 - 101。俄文。该研究的相关性与现代高性能计算系统、超级神经计算机和人工智能设备的快速发展有关。今天,这种发展受到阻碍,很大程度上是由于缺乏有效的冷却系统为其结构的大功率元件。Cu-SiC复合材料具有较好的物理、机械和热物理特性,可用于解决除热强化问题。该研究的主要目的是通过火花等离子烧结获得具有改善物理、机械和热特性的金属基Cu-10% SiC复合材料的大块产品。研究对象为Cu-10%SiC金属基复合材料的块状产品。分别在温度为700、750、800、850℃和压力为60 MPa的条件下进行放电等离子烧结。方法:火花等离子烧结、x射线衍射(x射线相分析)、扫描电镜、压痕法、激光闪蒸法。结果。以铜为基体,加入cu -10%碳化硅增强超硬颗粒,制备了块状金属基复合材料。在700、750、800和850℃的不同温度下,对分散的复合材料进行了放电等离子烧结。研究了初始分散材料和最终散装产品的微观结构和组成。结果表明,火花等离子体烧结法具有制备密度较高、物理、机械和热性能优良的材料的优点。对所得样品的分析表明,形成了致密(高达~ 88%)均匀的细晶复合组织。该复合材料在850℃的最高烧结温度下致密化程度最高,硬度最高(H= 3.63 GPa),杨氏模量最高(E= 159.63 GPa),室温下导热系数最高(λ=223 W/m K),可作为节能导热系统的结构和功能材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
OBTAINING BULK PRODUCTS FROM CU-SIC METAL-MATRIX COMPOSITE FOR ENERGY-EFFICIENT HEAT-CONDUCTING SYSTEMS
Link for citation: Nikitin D.S., Shanenkov I.I., Nassyrbayev A., Vympina Yu. N., Orlova E.G., Ivashutenko A.S., Sivkov A.A.  Obtaining bulk products from Cu-SiC metal-matrix composite for energy-efficient heat-conducting systems. Bulletin of the Tomsk Polytechnic University. Geo Аssets Engineering, 2023, vol. 334, no. 7, рр. 93-101. In Rus. The relevance of the research is associated with the rapid development of modern high-performance computing systems, superneurocomputers and artificial intelligence devices. Today such development is held back largely due to the lack of an effective cooling system for high-power elements of their structures. Composite materials Cu-SiC with improved physical, mechanical and thermophysical characteristics can be used to solve problems of heat removal intensification. The main aim of the research is to obtain bulk products from metal-matrix composite Cu-10% SiC with improved physical, mechanical and thermal characteristics by spark plasma sintering. Objects of the research are bulk products from metal-matrix composite Cu-10%SiC. The samples were obtained by spark plasma sintering at temperatures of 700, 750, 800, 850 °C and a pressure of 60 MPa. Methods: spark plasma sintering, X-ray diffractometry (X-ray phase analysis), scanning electron microscopy, indentation, laser flash method. Results. Experimental studies have been carried out to obtain bulk metal-matrix composites with a copper matrix and the addition of reinforcing superhard particles of silicon carbide Cu-10%SiC. The compaction of dispersed composite materials was carried out by spark plasma sintering at various temperatures of 700, 750, 800, and 850 °C. The microstructure and composition of initial dispersed materials and final bulk products have been studied. It is shown that the spark plasma sintering method has advantages for obtaining relatively dense materials with high physical, mechanical and thermal properties. Analysis of the obtained samples showed the formation of a dense (up to ~88 %) homogeneous fine-grained composite structure. The greatest densification of the material is achieved at the highest sintering temperature of 850 °C, which causes this sample to demonstrate the maximum hardness (H=3,63 GPa) and Young's modulus (E=159,63 GPa), as well as the thermal conductivity at room temperature (λ=223 W/m K). The obtained composite materials can be used as structural and functional materials for energy-efficient heat-conducting systems.
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