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双波纹流道中的流体流动特性及LDV实验 被引量:3

LDV experiment and characteristics of fluid flow in double wavy channel
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摘要 开发了一种双波纹流道结构,基于正交实验方法设计了9组不同结构参数的双波纹流道,采用计算流体力学(CFD)方法,研究了一定Reynolds数范围内(25≤Re≤200),9组双波纹流道内的流体充分发展层流流动和传热性能。研究结果表明,流道的波纹波幅对于流体流动和传热性能的影响较大。设计制作了流体在双波纹流道中流动的冷模实验装置,采用激光多普勒测速仪(LDV)对于流道内特殊位置点的速度进行测量,将实验测量结果与数值模拟计算结果进行对比。结果表明,实验测量结果与数值模拟计算结果变化趋势一致且吻合较好,主流速度的最大相对误差为28.7%,由此验证了数值模拟计算的可靠性和准确度。 A new special channel named as double wavy channel is presented. Based on the method of orthogonal experiments, 9 double wavy channels with different structural parameters were designed. In certain Reynolds number range (25≤Re≤200), the characteristics of fully developed laminar flow and heat transfer for the 9 double wavy channels were considered using computational fluid dynamics technology. The fluid flow experimental set for the channel was designed and manufactured, and flow velocities of special points in the channel were measured using laser Doppler velocimeter. It is concluded that the wave amplitude of the channel has significant effect on the characteristics. The numerical simulation results are in accordance with the experimental results and the maximum relative error of the main velocity is 28.7%. The validity and accuracy of the numerical simulation are verified.
作者 王丹 王珂 王永庆 刘敏珊
机构地区 郑州大学河南省过程传热与节能重点实验室
出处 《化工学报》 EI CAS CSCD 北大核心 2014年第10期3769-3775,共7页 CIESC Journal
基金 国家自然科学基金项目(51376163)~~
关键词 计算流体力学 层流 传热 双波纹流道 正交实验 激光多普勒测速仪 computational fluid dynamics laminar flow heat transfer double wavy channel orthogonal experiment laser Doppler velocimeter
分类号 TQ124 [化学工程—无机化工]
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参考文献20

  • 1丁蓉,宣益民.波纹流道中流体流动特性的数值与实验研究[J].化工学报,2000,51(5):708-712. 被引量:5
  • 2谢公南,王秋旺,曾敏,罗来勤.几何因子对波纹通道内稳态流动与换热的影响[J].计算物理,2007,24(2):192-196. 被引量:3
  • 3师晋生.波纹通道内充分发展层流流动的简化分析[J].热能动力工程,2010,25(6):668-671. 被引量:2
  • 4Metwally H M, Manglik R M. Numerical solutions forperiodically-developed laminar flow and heat transfer in sinusoidalcorrugated plate channels with constant wall temperature//Proceedingsof NHTC’00:34th National Heat Transfer Conference [C]. Pittsburgh,Pennsylvania, 2000: 171-178.
  • 5Manglik R M, Zhang J, Muley A. Low Reynolds number forcedconvection in three-dimensional wavy-plate-fin compact channels: findensity effects [J]. International Journal of Heat and Mass Transfer,2005, 48 (8): 1439-1449.
  • 6Metwally H M, Manglik R M. Enhanced heat transfer due tocurvature-induced lateral vortices in laminar flows in sinusoidalcorrugated-plate channels [J]. International Journal of Heat and MassTransfer, 2004, 47 (10/11): 2283-2292.
  • 7Zhang J, Kundu J, Manglik R M. Effect of fin waviness and spacingon the lateral vortex structure and laminar heat transfer inwavy-plate-fin cores [J]. International Journal of Heat and MassTransfer, 2004, 47 (8/9): 1719-1730.
  • 8Yang L C, Asako Y, Yamaguchi Y, et al. Numerical prediction oftransitional characteristics of flow and heat transfer in a corrugatedduct [J]. Journal of Heat Transfer, 1997, 119 (1): 62-69.
  • 9Rokni M, Sundén B. 3D numerical investigation of turbulent forcedconvection in wavy ducts with trapezoidal cross-section [J].International Journal of Numerical Methods for Heat & Fluid Flow,1998, 8 (1): 118-141.
  • 10Utriainen E, Sundén B. Numerical analysis of primary surfacetrapezoidal cross wavy duct [J]. International Journal of NumericalMethods for Heat & Fluid Flow, 2000, 10 (6): 634-648.

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共引文献7

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二级引证文献5

化工学报
2014年 第10期

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