本研究主要可以分成兩部份，首先水流以浸沒方式模擬洪水通過連續式透水結構物，探討平均流與紊流之特性，利用實驗室中15m×0.6m ×0.6m之循環渠道配合音波都普勒流速儀（acoustic Doppler Velo- cimeter，ADV）進行量測試驗，研究結果瞭解水流通過浸沒連續式透水結構物相應之流速、紊流強度、紊流動能及雷諾剪力分布情形；另一方面，本研究與Cui（2002）所做的連續式不透水結構物數值模擬結果比較，比較結果得知透水結構物後方的回流區只有一個，並無發現結構物前方的回流區與後方的角落渦流，且回流區大小較不透水結構物來得窄且短，發生位置也因通過結構物穿越流的影響出現在較下游處，底床剪應力亦由於回流區的不同，使得剪應力正負值不如不透水結構物轉換頻繁，呈現較為均勻的狀況。最後，本文利用分析結果提出本實驗成果在工程上的應用。

The purpose of this study can be divided into two parts. First, Water immerged situations are used to simulate the flood water through the Series porous structures. There is a circulated flume(15m × 0.6m × 0.6m) with acoustic Doppler Velocimeter (ADV) for measuring. Discussion on the averaged flow and turbulence characteristics is proposed here. This part is to understand the velocity, turbulence intensity, turbulent kinetic energy and Reynolds shear distributions related to the flood flow through the immerged Series porous structures. On the other hand, the present results are used to compare with the existing numerical results of series impermeable structures of Cui(2002). This comparison shows that the water behind the series porous structures have only one recirculation region, and there is no recirculation region in front of the structure and the corner eddy current, compared with the series impermeable structures. Location the recirculation is affected as a result of bleed flow to take place in a more downstream point, Bed shear stress is also due to the different recirculation region, so the shear stress is not as impermeable as so many positive and negative conversion., The present results of this experiment can be applied to engineering applications.

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