Monitoring outer surface temperature to assess thermal fatigue at T-junctions

IF 2.1 3区工程技术 Q1 NUCLEAR SCIENCE & TECHNOLOGY Nuclear Engineering and Design Pub Date : 2024-12-01 Epub Date: 2024-10-05 DOI:10.1016/j.nucengdes.2024.113622

Koji Miyoshi

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Abstract

Mixing fluids at different temperatures in T-junctions can lead to the formation of cracks from thermal fatigue. In this study, mock-up tests and analyses were conducted to develop a monitoring procedure for the temperature fluctuation on the pipe inner surface using temperature measurements of the outer surface at a T-junction. In the tests, the temperatures on the inner and outer surfaces at the T-junction were measured with thermocouples and thermography, respectively. Both the distributions of the time- averaged temperature and the temperature fluctuation range on the outer surface measured by thermography were similar to those on the inner surface measured with the thermocouples. The temperature fluctuation range and accumulated fatigue damage on the inner surface were estimated using the developed inverse analysis. Since the measured temperature on the outer surface includes noise for the high frequency component, the cut-off frequency should be determined prior to making the inverse analysis. The prediction accuracy, however, can be improved for high temperature conditions such as actual plants.

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监测外表面温度以评估 T 型接头的热疲劳

在 T 型接头处混合不同温度的流体可能会导致热疲劳裂纹的形成。在这项研究中，我们进行了模拟试验和分析，以便利用 T 型接头处外表面的温度测量结果，制定管道内表面温度波动的监测程序。在测试中，分别使用热电偶和热成像技术测量了 T 型接头处内表面和外表面的温度。热成像仪测量的外表面时间平均温度分布和温度波动范围与热电偶测量的内表面温度分布相似。内表面的温度波动范围和累积疲劳损伤是通过所开发的反分析方法估算出来的。由于外表面测得的温度包含高频成分的噪声，因此在进行反分析之前应确定截止频率。不过，在实际工厂等高温条件下，预测精度还可以提高。

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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来源期刊

Nuclear Engineering and Design 工程技术-核科学技术

CiteScore

3.40

自引率

11.80%

发文量

377

审稿时长

5 months

期刊介绍： Nuclear Engineering and Design covers the wide range of disciplines involved in the engineering, design, safety and construction of nuclear fission reactors. The Editors welcome papers both on applied and innovative aspects and developments in nuclear science and technology. Fundamentals of Reactor Design include: • Thermal-Hydraulics and Core Physics • Safety Analysis, Risk Assessment (PSA) • Structural and Mechanical Engineering • Materials Science • Fuel Behavior and Design • Structural Plant Design • Engineering of Reactor Components • Experiments Aspects beyond fundamentals of Reactor Design covered: • Accident Mitigation Measures • Reactor Control Systems • Licensing Issues • Safeguard Engineering • Economy of Plants • Reprocessing / Waste Disposal • Applications of Nuclear Energy • Maintenance • Decommissioning Papers on new reactor ideas and developments (Generation IV reactors) such as inherently safe modular HTRs, High Performance LWRs/HWRs and LMFBs/GFR will be considered; Actinide Burners, Accelerator Driven Systems, Energy Amplifiers and other special designs of power and research reactors and their applications are also encouraged.