纵向肋强化波纹螺旋通道流动与传热性能

    Flow and heat transfer performances of the corrugated spiral channel with longitudinal fins

    • 摘要: 螺旋通道换热器广泛应用于农业工程领域,为了进一步提升螺旋通道的传热性能,该研究提出了一种带纵向肋的矩形截面波纹螺旋通道,数值研究了波纹数和纵向肋几何参数对通道内流体流动与传热性能的影响。结果表明:增加波纹螺旋通道的波纹数,使得通道在层流状态下产生了多涡结构,增加了通道的综合换热性能。在雷诺数Re=750,波纹数n=18 时,相比于光滑螺旋通道,波纹螺旋通道内综合换热评价指标最高增加了 27.66%。在此基础上,在通道内增加纵向肋,通过数值模拟观察到纵向肋诱导产生了纵向涡。在纵向肋高度不变的情况下,随着纵向肋宽度的增加,通道的综合换热评价指标存在最大值。当Re=250,肋宽为1/3通道宽度,肋高为1/16通道高度时,相比于波纹螺旋通道,纵向肋波纹螺旋通道的综合换热评价指标最高为1.157。在纵向肋宽度一定的情况下,增加纵向肋高度使通道的综合换热评价指标呈现先增大后减小的趋势。研究结果可为纵向肋波纹螺旋通道的设计及优化提供参考。

       

      Abstract: Heat exchangers serve as pivotal components in heat exchange systems. Compared with the straight channels, spiral channels have better performance due to the curvature of the centrifugal force generated by the secondary flow. Consequently, heat exchangers employing spiral channels find widespread application in agricultural engineering, including greenhouse air conditioning, water circulation systems, and agricultural product processing and storage for effective heat management. In this paper, we propose enhancing the heat transfer efficiency of spiral channels by introducing corrugations with longitudinal fins on the outer channel wall. To elucidate the impact of corrugation, we establish three-dimensional models of smooth spiral channels, corrugated spiral channels, and corrugated spiral channels with longitudinal fins. Initially, we investigate the influence of corrugated number on flow and heat transfer performance numerically. Through comparative analysis involving the development and variation of velocity and vorticity fields, average Nusselt number Nu, fanning friction factor f, average Dean number Dnm, secondary flow intensity Se under different corrugated numbers, and the performance evaluation factor of heat exchanger based on comprehensive (PEC0), insights are drawn. Subsequently, longitudinal fins are integrated into the corrugated spiral channel, and a numerical study is conducted to assess the effect of varying geometric parameters of the longitudinal fin on the fluid flow and heat transfer performance inside the channel. Analysis of different longitudinal fin widths and heights on velocity and temperature fields, Nu, f, and performance evaluation factor of heat exchanger based on comprehensive (PECw) of the channel is performed. The findings indicate that corrugated spiral channels outperform smooth spiral channels in heat transfer and flow performance. With increasing corrugated number n, secondary flow intensity within the corrugated spiral channel intensifies. Notably, at a Reynolds number of 550, a multi-vortex structure emerges in the corrugated spiral channel with a corrugated number of 21. At Reynolds number 750 and corrugated number 21, the Nusselt number of corrugated spiral channel increases by 47.08% compared to the smooth spiral channel. At the same time, the resistance loss in the channel also increases, and the Fanning friction factor of the corrugated spiral channel increases by 59.20%. When the Reynolds number is 750, the PEC0 of the corrugated spiral channel with 18 corrugations is the highest, which increases by 27.66% compared to the smooth spiral channel. On this basis, longitudinal fins are added to the corrugated spiral channel, and it is observed by numerical simulation that symmetrical longitudinal vortices are induced by the fins. Further, the longitudinal fins induce symmetrical longitudinal vortices, enhancing flow and heat transfer in the channel's middle section. Under the condition of constant fin width and increasing fin height, the comprehensive heat transfer performance of the channel has a maximum value, that is, when fin width w=W/3, fin height h=H/6 and Reynolds number Re=250, the highest PECw is 1.157. When the fin height is fixed, increasing the fin width w will also make the PECw of the channel first increase and then decrease. The correlation formulas for Nusselt number Nu, Fanning friction factor f and secondary flow intensity Se in corrugated spiral channel are fitted, with deviations within ±14.0%, ±10.2% and ±4.4%, respectively. This provides a certain reference for the application of corrugated spiral channels with longitudinal fins in the thermal design and usage of heat exchangers.

       

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