Mechanical And Microstructural Performance Evaluation Of Diffusion Bonded Alloy 800H For Very High Temperature Nuclear Service

IF 1.5 4区 材料科学 Q3 ENGINEERING, MECHANICAL
Heramb P. Mahajan, L. Maciel, T. Hassan
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引用次数: 5

Abstract

Very high temperature reactors (VHTRs) are planned to be operated between 550 to 950°C, and demand a thermally efficient intermediate heat exchanger (IHX) in the heat transport system (HTS). The current technological development of compact heat exchangers (CHXs) for VHTRs is at the ‘proof of concept’ level. A significant development in the CHX technologies is essential for the VHTRs to be efficient, cost-effective, and safe. CHXs have very high thermal efficiency and compactness, making them a prime candidate for IHXs in VHTRs. Photochemically etched plates with the desired channel pattern are stacked and diffusion bonded to fabricate CHXs. All plates are compressed at an elevated temperature over a specified period in the diffusion bonding process, promoting atomic diffusion and grain growth across bond surfaces resulting in a monolithic block. The diffusion bonding process changes the base metal properties, which are unknown for Alloy 800H, a candidate alloy for CHX construction. Hence, developing mechanical response data and understanding failure mechanisms of diffusion bonded Alloy 800H at elevated temperatures is a key step for advancing the technology of IHXs in VHTRs. The ultimate goal of this study is to develop ASME BPVC Section III, Division 5 design rules for CHXs in nuclear service. Towards this goal, mechanical performance and microstructures of diffusion bonded Alloy 800H is investigated through a series of tensile, fatigue, creep, and creep-fatigue tests at temperatures 550 to 760°C. The test results, failure mechanisms, and microstructures of diffusion bonded Alloy 800H is scrutinized and presented.
用于超高温核设施的扩散粘结合金800H的力学和微观结构性能评价
超高温反应堆(vhtr)计划在550至950°C之间运行,并且在传热系统(HTS)中需要一个热效率高的中间热交换器(IHX)。目前用于vhtr的紧凑型热交换器(chx)的技术发展处于“概念验证”水平。CHX技术的重大发展对于vhtr的效率、成本效益和安全性至关重要。chx具有非常高的热效率和紧凑性,使其成为vhtr中ihx的主要候选材料。光化学蚀刻板与所需的通道模式是堆叠和扩散键合,以制造chx。在扩散键合过程中,所有的板在指定的时间内在高温下被压缩,促进原子扩散和晶粒在键合表面的生长,从而形成一个整体块。扩散连接过程改变了基体金属的性能,而对于CHX结构的候选合金Alloy 800H来说,这是未知的。因此,研究扩散键合合金800H在高温下的力学响应数据,了解扩散键合合金800H在高温下的失效机理,是推进高温高温堆IHXs技术的关键一步。本研究的最终目标是为核服务中的chx制定ASME BPVC Section III, Division 5设计规则。为此,在550 ~ 760℃的温度下,通过一系列拉伸、疲劳、蠕变和蠕变疲劳试验,研究了扩散结合合金800H的力学性能和显微组织。详细介绍了扩散焊合金800H的试验结果、失效机理和微观组织。
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来源期刊
CiteScore
3.00
自引率
0.00%
发文量
30
审稿时长
4.5 months
期刊介绍: Multiscale characterization, modeling, and experiments; High-temperature creep, fatigue, and fracture; Elastic-plastic behavior; Environmental effects on material response, constitutive relations, materials processing, and microstructure mechanical property relationships
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