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气固搅拌流化床压力脉动的小波分析 被引量:12

Wavelets analysis of pressure fluctuation in agitated fluidized bed
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摘要 在内径188mm、静床高400mm的搅拌流化床中,采用GeldartD类颗粒为实验物料,通过小波分析研究了不同气速和搅拌桨转速下搅拌流化床的压力脉动行为.实验发现,搅拌桨的转动作用促使在普通流化床中不易散式流态化的D类颗粒形成了散式流态化.随着气速的增加,第1尺度的小波能量特征值在某一个气速范围内发生急剧变化,进而提出了将该气速范围的下限和上限分别定义为临界鼓泡速度和充分鼓泡速度的判据.随搅拌转速的增加,散式流态化的气速操作范围线性增加.在鼓泡流态化状态下,气速是流化床气泡行为的主导因素,搅拌桨转速的增加对气泡产生的频率无明显影响但可使气泡的直径变小. In an agitated fluidized bed using Geldart D particles as fluidized materials with a static bed height of 400 mm and an inner diameter of 188 mm, the pressure fluctuation signals at different rotation speeds of stirrer blade and gas velocities were analyzed with the wavelet analysis method for investigating the influence of agitation of stirrer blade on the fluidization behavior. The pressure fluctuation signals were decomposed into 9 scales by Dau2 wavelet. Experimental results indicated that the wavelet energy characteristics of Scale 1 detailed signal changed sharply in a certain range of gas velocity. Then the criteria of the minimum bubbling velocity and full bubbling velocity were developed. The Geldart D particles showed particulate fluidization due to the rotation of stirrer blade. The minimum bubbling velocity and full bubbling velocity increased linearly with increasing rotation speeds of stirrer blade, while the fluidized bed transformed from bubbling fluidization to particulate fluidization. Gas velocity was the major cause for the pressure fluctuation in the bubbling fluidization regime and increasing rotation speed of stirrer blade had little effect on the bubble frequency, but made the bubble size smaller obviously.
出处 《化工学报》 EI CAS CSCD 北大核心 2006年第12期2854-2859,共6页 CIESC Journal
基金 国家自然科学基金重大项目(20490200) 国家重点基础研究专项经费资助项目(2005CB623804)~~
关键词 搅拌流化床 压力脉动 小波分析 散式流态化 agitated fluidized bed pressure fluctuation wavelet analysis particulate fluidization
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参考文献18

  • 1李凡,冯连芳,顾雪萍,王凯,刘波.气固搅拌流化床的床层压降[J].高校化学工程学报,2002,16(4):384-388. 被引量:11
  • 2Leva M.Pressure drop and power requirements in a stirred fluidized bed.AIChE J.,1960,6(4):688-692
  • 3Fan L T,Ho Thoching,Hiraoka S,Walawender W P.Pressure fluctuations in a fluidized bed.AIChE J.,1981,27(3):388-396
  • 4Zhao Guibing,Yang Yongrong.Multiscale resolution of fluidized-bed pressure fluctuations.AIChE J.,2003,49(2):869-882
  • 5Lu Xuesong,Li Hongzhong.Wavelet analysis of pressure fluctuation signals in a bubbling fluidized bed.Chemical Engineering Journal,1999,75(2):113-119
  • 6Park S H,Kang Y,Kim S D.Wavelet transform analysis of pressure fluctuation signals in a pressurized bubble column.Chemical Engineering Science,2001,56(21):6259-6265
  • 7Guo Qingjie,Yue Guangxi,Suda Toshiyuki,Sato Junichi.Flow characteristics in a bubbling fluidized bed at elevated temperature.Chemical Engineering and Processing,2003,42(6):439-447
  • 8冀海峰,黄志尧,吴贤国,李海青.基于小波变换的气固流化床压力波动信号的分析[J].高校化学工程学报,2000,14(6):553-557. 被引量:25
  • 9Li Jinghai.Compromise and resolution-exploring the multi-scale nature of gas-solid fluidization.Powder Technology,2000,111(1):50-59
  • 10Ren Jinqiang,Mao Qiming,Li Jinghai,Li Weigang.Wavelet analysis of dynamic behavior in fluidized beds.Chemical Engineering Science,2001,56(3):981-988

二级参考文献52

  • 1刘得金,李洪钟.固体表面活性对液固流态化的影响[J].化工冶金,1994,15(2):183-186. 被引量:2
  • 2王定松.丙烯气相聚合反应工程研究进展[J].石油化工,1995,24(6):431-436. 被引量:1
  • 3Johnsson F, Zijerveld R C, Schouten J C, Van den Bleek C M, Leekner B. Charaeterization of Fluidization Regimes by Time-series Analysis of Pressure Fluctuations. Int.J.Multi. Flow, 2000, 26:663--715.
  • 4Huan Zhong, Bakshi B R, Peijun Jiang, Fan L S. Multifractal Characterization of Flow in Circulating Fluidized Beds.Chem Eng. J., 1996, 64 (1): 107--115.
  • 5Arneodo A, Bacry E, Muzy J F . The Thermodynamics of Fractals Revisited with Wavelets. Physical A, 1995, 213:232--275.
  • 6Meyer Y. Wavelets and Applications. Berlin: Springer-Verlag, 1992.
  • 7Robert C Zijerveld, Filip Johnsson, Antonio Marzocchella,Jaap C Schouten, Cor M van den Bleek. Fluidization Regimes and Transitions from Fixed Bed to Dilute TransportFlow. Powder Technology, 1998, 95 : 185--204.
  • 8Antoni Marzocchella, Zijerveld R C, Schouten J C, Van den Bleek C M. Chaotic Behavior of Gas-Solids Flow in the Riser of a Laboratory-scale Circulating Fluidized Bed. AIChE J. , 1997,43 (6):1458--1468.
  • 9Schouten J C, Zijerveld R C, Van den Bleek C M. Scale-up of Bottom-bed Dynamics and Axial Solids-distribution in Circulating Fluidized Beds of Geldart-B Particles. Chem. Eng. Sci. , 1999,54:2103--2112.
  • 10Brereton C M H, Grace J R. Microstructural Aspects of the Behaviour of Circulating Fluidized Beds. Chem. Eng. Sci. ,1993, 48 (14): 2565--2572.

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