印刷电路热交换器芯在张力和压力载荷下的力学性能评价

Heramb P. Mahajan, L. Maciel, G. Ngaile, T. Hassan
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引用次数: 0

摘要

印刷电路热交换器(PCHE)具有小通道和高表面积,使其成为下一代核电站(NGNPs)的有效解决方案。这些PCHEs是通过扩散键合工艺制造的。这一加工步骤改变了锻造金属板的微观结构。由于缺乏测试数据,目前的ASME设计规范不支持核电机组的PCHE设计。因此,对扩散键合材料的高温力学性能表征已经有了初步的研究。最常见的通道形状之一是带有尖角的半圆形通道。这些角在扩散键合界面处起到应力提升的作用。在应力上升管存在的情况下,评估扩散粘结材料的高温力学性能是制定PCHE设计ASME规范的重要步骤。本研究选择了两种试样几何形状:第一种是具有三排三列通道的拉伸加载PCHE棒状试样,第二种是具有六排八列通道的实验室规模PCHE。通过对PCHE杆试件进行高温单调和循环试验,评估其在轴向拉伸载荷作用下的力学性能,研究其破坏机理。实验室规模的PCHE试件在室温超压载荷、压力蠕变和压力蠕变疲劳载荷下进行了测试,以模拟典型NGNPs中观察到的真实载荷条件。通道标本的x射线扫描显示出有趣的观察结果。文中给出了试验结果和观察结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mechanical Performance Evaluation of the Printed Circuit Heat Exchanger Core Experiments Under Tension and Pressure Loading
The printed circuit heat exchanger (PCHE) has small channels with high surface area, making them an efficient solution for next-generation nuclear plants (NGNPs). These PCHEs are fabricated through a diffusion bonding process. This fabrication step changes the microstructure of wrought metal plates. The current ASME design code does not support the PCHE design for NGNPs due to a lack of test data. Hence, there has been initiative towards elevated temperature mechanical property characterization of the diffusion bonded material. One of the most common channel shapes is a semicircular channel with sharp corners. These corners act as a stress riser at the diffusion bonding interface. Evaluating elevated temperature mechanical performance of diffusion bonded material in the presence of stress risers is an essential step towards the ASME code development of PCHE design. This study selected two specimen geometries: the first is a PCHE bar specimen for tensile loading with three rows and three columns of channels, and the second is a lab-scaled PCHE with six rows and eight columns of channels. A set of elevated temperature monotonic and cyclic tests were conducted on the PCHE bar specimen to evaluate the mechanical performance under axial tensile loadings to study the failure mechanism. The lab-scaled PCHE specimens were tested under overpressure loads at room temperature, and pressure creep and pressure creep-fatigue loadings to mimic the realistic loading conditions observed in typical NGNPs. The X-ray scans of channeled specimens show interesting observations. The test results and observations are presented in the paper.
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