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基于分数阶Maxwell模型的振荡流传热特性分析 被引量:1

Theoretical analysis of heat transfer in oscillating flows with fractional Maxwell model
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摘要 经求解基于分数阶Maxwell模型的粘弹性流体在周期性振荡压力梯度下,圆直管内的运动方程和能量方程,得到了振荡管流换热的速度分布、温度分布以及热扩散系数的解析解形式.通过对无量纲热扩散系数的分析可知,影响粘弹性流体管内振荡流轴向换热的无量纲参数有:Womersley数Wo、Deborah数De、无量纲振幅Δx/R和流体普朗特数Pr.分数阶Maxwell模型振荡流传热也存在粘弹性流体流动中存在的共振现象,且共振峰的数量随De数的减小而增加,发生共振的起始频率随De数的减小而降低.共振峰值出现的位置即频率值与Pr和无量纲振幅Δx/R无关. By solving the momentum and energy equations of the oscillating flow with the fractional Max well model, which is driven by a sinusoidally varying pressure gradient, the general analytical solutions of the velocity profile, the temperature profile and the enhanced thermal diffusivity were obtained. Based upon the a nalysis of the enhanced thermal diffusivity, it is found that the parameters influenced the enhanced heat trans fer for the problem are the Womersley number Wo, the Deborah number De, the dimensionless amplitude △x/ R and the Prandtl number of the fluid Pr. The heat transfer with fractional Maxwell model exhibits resonance phenomena similar to the flow of the viscoelastic fluid. And the number of the resonance peaks increases with the decrease of De, the frequency of the first peak decreases with the decrease of De. In addition, the frequen cies where the resonance occurs are not concerned with the Pr and △x/R.
作者 李明震 董金钟
机构地区 北京航空航天大学能源与动力工程学院
出处 《北京航空航天大学学报》 EI CAS CSCD 北大核心 2012年第11期1562-1566,共5页 Journal of Beijing University of Aeronautics and Astronautics
关键词 分数阶Maxwell模型 振荡流 传热 粘弹性流体 管流 fractional Maxwell model oscillating flow heat transfer viscoelastic fluid pipe flow
分类号 TK124 [动力工程及工程热物理—工程热物理]
  • 相关文献

参考文献14

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二级参考文献10

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共引文献1

同被引文献22

  • 1李远禄,于盛林,郑罡.非整数阶系统频域辨识的递推最小二乘算法[J].信息与控制,2007,36(2):171-175. 被引量:6
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引证文献1

二级引证文献8

北京航空航天大学学报
2012年 第11期

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