Flow Patterns Identification in a High-flux Circulating Fluidized Bed with Shannon Entropy Increment Rate

Shang Yi Yin; Bao Sheng Jin; Wen Qi Zhong

doi:10.4028/www.scientific.net/AMR.732-733.194

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Flow Patterns Identification in a High-flux Circulating Fluidized Bed with Shannon Entropy Increment Rate

Abstract:

Experiments of gas-solid suspension were carried out in a high-flux circulating fluidization bed with the solid mass flux up to 536 kg/(m²·s). Differential pressure fluctuation time series were obtained at different locations in the riser. Shannon entropy increment rate analysis was developed to identify the flow pattern and transformation and characterize the dynamic behavior. Effect of superficial gas velocity on the Shannon entropy increment rate was examined under high solid mass flux. It was demonstrated that a circulating fluidization bed at high solid mass flux was a deterministic chaos system and the sensitivity of the system's chaotic characteristic to operating parameters at different flow regimes was different. Shannon entropies increment rate of different flow regimes were distinct. Shannon entropy increment rate analysis method results in high degree of recognition for flow pattern and transformation.