Development of the Multichannel Pulsed Ultrasonic Doppler Velocimeter for the measurement of liquid metal flow

arXiv - PHYS - Fluid Dynamics Pub Date : 2024-09-04 DOI:arxiv-2409.02815

Ding-Yi Pan, Yi-Fei Huang, Ze Lyu, Juan-Cheng Yang, Ming-Jiu Ni

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Abstract

In the present study, by adopting the advantage of ultrasonic techniques, we developed a Multichannel Pulsed Ultrasonic Doppler Velocimetry (MPUDV) to measure the 2D2C velocity fields of liquid metal flow. Due to the specially designed Ultrasonic host and post-processing scheme, the MPUDV system can reach a high spatiotemporal resolution of 50 Hz and 3 mm. The flow loop contains a cavity test section to ensure a classical recirculating flow was built to validate the accuracy of MPUDV in velocity field measurement. In the initial phase of the study, water with tracer particles was selected as the working liquid to ensure the velocity field measurements by the well-developed Particle Image Velocimetry (PIV). A comparison of the data obtained from the PIV and MPUDV methods revealed less than 3 differences in the 2D2C velocity field between the two techniques during simultaneous measurements of the same flow field. This finding strongly demonstrates the reliability of the MPUDV method developed in this paper. Moreover, the ternary alloy GaInSn was selected as the working liquid in the flow loop to validate the efficacy of the MPUDV in measuring 2D-2C velocity fields. A series of tests were conducted in the cavity at varying Reynolds numbers, ranging from 9103 to 24123. The measurements demonstrated that the MPUDV could accurately measure the flow structures characterized by a central primary circulation eddy and two secondary eddies in the opaque liquid metal. Furthermore, it was found that the vortex center of the primary circulating eddy and the size of the secondary eddies undergo significant alterations with varying Reynolds numbers, indicating the influence of inertial force on the flow characteristics in the recirculating flow. It is therefore demonstrated that the current MPUDV methodology is applicable for measuring a 2D2C velocity field in opaque liquid metal flows.

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开发用于测量液态金属流动的多通道脉冲超声多普勒速度计

本研究利用超声波技术的优势，开发了多通道脉冲超声多普勒测速仪（MPUDV），用于测量液态金属流动的二维二氯甲烷速度场。由于采用了专门设计的超声波主机和后处理方案，MPUDV 系统可以达到 50 Hz 和 3 mm 的高时空分辨率。为了验证 MPUDV 在速度场测量中的准确性，建立了包含空腔测试部分的流动环路，以确保经典的再循环流动。在研究的初始阶段，选择含有示踪粒子的水作为工作液体，以确保通过成熟的粒子图像测速仪（PIV）进行速度场测量。对 PIV 和 MPUDV 方法获得的数据进行比较后发现，在同时测量同一流场时，两种技术的 2D2C 速度场相差不到 3。这一结果有力地证明了本文所开发的 MPUDV 方法的可靠性。此外，为了验证 MPUDV 在测量 2D-2C 速度场方面的有效性，我们选择了三元合金 GaInSn 作为流动回路中的工作液体。在不同雷诺数（从 9103 到 24123）的空腔中进行了一系列测试。测量结果表明，MPUDV 可以准确测量不透明液态金属中由一个中心主循环涡和两个次级涡构成的流动结构。此外，还发现主循环涡旋中心和次级涡旋的大小随雷诺数的变化而发生显著变化，这表明惯性力对再循环流的流动特性有影响。由此证明，当前的 MPUDV 方法适用于测量不透明液态金属流中的 2D2C 速度场。

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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arXiv - PHYS - Fluid Dynamics

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