Measurement of Local Mass Flux in a Circulating Fluidized Bed Using a Phase Doppler Particle Analyzer: A New Post-Processing Data Algorithm

Heat Transfer: Volume 3 — Experimental Studies in Multiphase Flow; Multiphase Flow in Porous Media; Experimental Multiphase Flows and Numerical Simulation of Two-Phase Flows; Fundamental Aspects of Experimental Methods Pub Date : 1996-11-17 DOI:10.1115/imece1996-0117

T. V. D. Moortel, R. Santini, L. Tadrist

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引用次数: 2

Abstract

This study focused on the measurement of solid mass flux in the riser of a CFB cold pilot. The investigations were carried out using a Phase Doppler Particle Analyzer (PDPA). Inconsistencies in PDPA results were observed when investigating flows with high particle densities. It appears that the performance of the measuring technique was affected by the optical thickness of the measured medium, thus producing substantial overestimation of the global solid phase quantity (e.g., solid mass flux). To determine the origin of these inconsistencies, the measuring system was subjected to complete recalibration. It was found that in flows with high particle densities, noisy doppler signals tend to be split into several parts by the burst detector system, thus producing inconsistencies in the number of particles counted. The parameters associated with the splitting events were analyzed, and a post-processing algorithm was developed to limit PDPA measuring errors. The aim of the post-processing algorithm was to rebuild the data and to recover the original measurements. The reconstitution process was applied to solid mass flux measurements in a CFB cold pilot.

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用相位多普勒颗粒分析仪测量循环流化床的局部质量通量:一种新的后处理数据算法

本文研究了循环流化床冷先导器提升管内固体质量通量的测量。利用相位多普勒粒子分析仪(PDPA)进行了研究。在研究高颗粒密度的流动时，观察到PDPA结果的不一致性。测量技术的性能似乎受到被测介质的光学厚度的影响，从而导致对整体固相数量(例如固体质量通量)的严重高估。为了确定这些不一致的来源，测量系统进行了完全的重新校准。研究发现，在高粒子密度的流体中，噪声多普勒信号容易被突发探测系统分解成几个部分，从而导致粒子数的不一致。分析了与分裂事件相关的参数，提出了一种限制PDPA测量误差的后处理算法。后处理算法的目的是重建数据，恢复原始测量值。将重构过程应用于循环流化床冷试验中固体质量通量的测量。

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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Heat Transfer: Volume 3 — Experimental Studies in Multiphase Flow; Multiphase Flow in Porous Media; Experimental Multiphase Flows and Numerical Simulation of Two-Phase Flows; Fundamental Aspects of Experimental Methods

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