Mechanical and Microstructural Characterization of Diffusion Bonded 800H

Heramb P. Mahajan, M. Elbakhshwan, B. Beihoff, T. Hassan
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引用次数: 1

Abstract

Compact heat exchangers have high compactness and efficiency, which is achieved by joining a stack of chemically etched channeled plates through diffusion bonding. In the diffusion bonding process, compressive stress is applied on plates at elevated temperatures for a specified period. These conditions lead to atomic diffusion, which results in the joining of all plates into a monolithic block. The diffusion bonding temperatures are above recrystallization temperatures, which changes the mechanical and microstructural properties of the bonded metal. Hence, diffusion bonded material needs mechanical and microstructural property evaluation. In this study, Alloy 800H is selected to study the influence of the diffusion bonding process on mechanical and microstructure properties of base metal. A series of tensile, fatigue, creep, and creep-fatigue experiments are conducted on base metal 800H (BM 800H) and diffusion bonded 800H (DB 800H) to explore the mechanical properties. Microstructure evolution during diffusion bonding is studied and presented in the paper. The mechanical and microstructural observations indicated ductile fracture at room temperature and brittle failure with bond delamination at elevated temperatures. The microstructure evolution during diffusion bonding is studied through tensile, fatigue, creep and creep-fatigue tests, and the implied root causes for the mechanical property changes are investigated. Efforts are made to correlate the microstructure change with mechanical property change in DB 800H.
扩散焊800H的力学和显微组织表征
紧凑型热交换器具有很高的紧凑性和效率,这是通过扩散键连接一堆化学蚀刻的通道板来实现的。在扩散键合过程中,压应力是施加在板在高温下一特定时期。这些条件导致原子扩散,这导致所有板连接成一个整体块。扩散键合温度高于再结晶温度,改变了键合金属的力学性能和显微组织性能。因此,需要对扩散键合材料的力学性能和显微组织性能进行评价。本研究选择Alloy 800H,研究扩散结合工艺对母材力学性能和显微组织性能的影响。在母材800H (BM 800H)和扩散焊800H (DB 800H)上进行了一系列拉伸、疲劳、蠕变和蠕变疲劳试验,探讨了其力学性能。本文对扩散连接过程中微观组织的演变进行了研究。力学和显微组织观察表明,室温下的韧性断裂和高温下的脆性破坏伴有粘结层脱层。通过拉伸试验、疲劳试验、蠕变试验和蠕变-疲劳试验,研究了扩散连接过程中微观组织的演变,探讨了力学性能变化的潜在根本原因。研究了db800h合金的显微组织变化与力学性能变化之间的关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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