Analysis of the Hydrodynamic Characteristics in a Rectangular Clarifier under Earthquake-Induced Sloshing

Turkish Journal of Civil Engineering Pub Date : 2023-05-01 DOI:10.18400/tjce.1268771

M. Aksel

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Abstract

Wastewater treatment plants, which play a crucial role in protecting the hydrosphere, are earthquake-prone infrastructures with large tanks and sensitive equipment. Damage to the structures in such facilities during seismic activity on the lithosphere can cause environmental pollution and threaten public health. Since the units/tanks in the treatment plants are not of different geometries and sizes, they may exceed the freeboard of the wave height due to the sloshing event. In this study, the sloshing dynamics of a rectangular type of clarifier were investigated. First, numerical parameters, boundaries, and initial conditions were validated using the results of an experimental campaign. Secondly, model conditions were kept constant, and geometry was enlarged (i.e., scaled-up) to investigate the variation of hydrodynamic forces near vulnerable equipment (such as scrapers and weirs) in clarifier. The numerical model was run for characteristics of two different earthquakes (i.e., Chi Chi-1999 and Kocaeli-1999). The results showed that dynamic pressure values near vulnerable equipment increased up to 120 times higher than the operating conditions. The maximum sloshing wave heights were calculated as 1.2 m and 1.45 m for Chi Chi (1999) and Kocaeli (1999) earthquakes, respectively.

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地震晃动作用下矩形澄清池水动力特性分析

污水处理厂在保护水圈方面起着至关重要的作用，它是具有大型水箱和敏感设备的地震易发基础设施。岩石圈地震活动对此类设施结构的破坏会造成环境污染，威胁公众健康。由于污水处理厂内的装置/水箱的几何形状和大小不一，它们可能会因晃动事件而超过干舷波高。本文研究了矩形澄清池的晃动动力学。首先，利用实验活动的结果验证了数值参数、边界和初始条件。其次，保持模型条件不变，并扩大几何形状(即按比例放大)，以研究澄清池中易损坏设备(如刮刀和堰)附近的水动力变化。数值模拟了Chi Chi-1999和Kocaeli-1999两次地震的特征。结果表明，易损设备附近的动压力值比正常工况增加了120倍。Chi Chi(1999)和Kocaeli(1999)地震的最大晃动波高分别为1.2 m和1.45 m。

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

Turkish Journal of Civil Engineering

CiteScore

1.70

自引率

0.00%

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