Structural Optimization and Flow Characteristics of the Interrupted Microchannels

doi:10.3901/JME.2023.04.274

Abstract

Abstract: The microchannel heat exchanger has obvious advantages in solving the problem of heat dissipation under high heat flux. In practical industrial applications, the integrated structure is usually adopted to improve the reaction efficiency, however, it is easy to affect the performance of heat transfer by uneven flow distribution in the process of reactor integration, and even leads to the phenomena of “dry steam”or“excessive liquid supply”. Therefore, the study of phase distribution characteristics in parallel microchannels has important guiding significance to improve the heat transfer efficiency. By optimizing the structure of the interrupted microchannel, a two-side-widened microchannel with transverse microcavities is proposed, the phase distribution uniformity of the new microchannel was determined by flow distribution, heat transfer characteristics, relative deviation of the two-phase distribution and pressure drop fluctuation. The results show that the structural optimization of the interrupted microchannel significantly improves the uniformity of phase distribution, and the relative deviation of gas flow in each branch pipe is less than 40%. The design of transverse microcavity makes two adjacent channels fully mixed, and the overall flow uniformity is improved by 37.5%. By widening the channel on both sides of the design, played a bubble filter, which reduce the pressure on both sides of the space and ensure the channel flow between the flow pattern and pressure consistency.

Key words: microchannel, gas-liquid two-phase flow, flow pattern, phase distribution, pressure drop

CLC Number:

TK513

TIAN Yusi, JIAO Yonggang, SUN Huikai, LIU Bin, HAN Fei. Structural Optimization and Flow Characteristics of the Interrupted Microchannels[J]. Journal of Mechanical Engineering, 2023, 59(4): 274-282.

References

[1] 王辉,汤勇,余建军. 相变传热微通道技术的研究进展[J]. 机械工程学报,2010(24):101-106. WANG Hui,TANG Yong,YU Jianjun. Recent advances of the phase change micro-channel cooling structure[J]. Journal of Mechanical Engineering,2010(24):101-106.
[2] LU M,WANG C C. Effect of the inlet location on the performance of parallel-channel cold-plate[J]. IEEE Transactions on Components and Packaging Technologies,2006,29(1):30-38.
[3] CHEIN R,CHEN J. Numerical study of the inlet/outlet arrangement effect on microchannel heat sink performance[J]. International Journal of Thermal Sciences,2009,48(8):1627-1638.
[4] XIA G,JIANG J,WANG J,et al. Effects of different geometric structures on fluid flow and heat transfer performance in microchannel heat sinks[J]. International Journal of Heat and Mass Transfer,2015,80:439-447.
[5] 贾玉婷,夏国栋,马丹丹,等. 水滴型凹穴微通道流动与传热的熵产分析[J]. 机械工程学报,2017,53(4):141-148. JIA Yuting,XIA Guodong,MA Dandan,et al. Entropy generation analysis of flow and heat transfer in microchannel with droplet reentrant cavities[J]. Journal of Mechanical Engineering,2017,53(4):141-148.
[6] LIU S,JIAO Y,GAO B,et al. Experimental and numerical study of two-phase flow in a rectangular mini-channel with sudden expansion structure[J]. Journal of Enhanced Heat Transfer,2020,27(2):173-194.
[7] SIVA V,PATTAMATTA A,DAS S. Effect of flow maldistribution on the thermal performance of parallel microchannel cooling systems[J]. International Journal of Heat and Mass Transfer,2014,73:424-428.
[8] XU J,GAN Y,ZHANG D Y,et al. Microscale heat transfer enhancement using thermal boundary layer redeveloping concept[J]. International Journal of Heat and Mass Transfer,2005,48(9):1662-1674.
[9] XU J,SONG Y,ZHANG W,et al. Numerical simulations of interrupted and conventional microchannel heat sinks[J]. International Journal of Heat and Mass Transfer,2008,51(11-26):5906-5917.
[10] YUE J,BOICHOT R,LUO L,et al. Flow distribution and mass transfer in a parallel microchannel contactor integrated with constructal distributors[J]. AICHE Journal,2009,56(2):298-317.
[11] DUAN C,LIU Z,ZHU C,et al. Distribution of gas-liquid two-phase flow in parallel microchannels with the splitting of the liquid feed[J]. Chemical Engineering Journal,2020,398:125630.
[12] LEE J,LEE S. Distribution of two-phase annular flow at header-channel junctions[J]. Experimental Thermal and Fluid Science,2002,28(2-3):217-222.
[13] REDO M A,JEONG J,GIANNETTI N,et al. Characterization of two-phase flow distribution in microchannel heat exchanger header for air-conditioning system[J]. Experimental Thermal and Fluid Science,2019,106:183-193.
[14] REDO M A,JEONG J,YAMAGUCHI S,et al. Characterization and improvement of flow distribution in a vertical dual-compartment header of a microchannel heat exchanger[J]. International Journal of Refrigeration,2020,116:36-48.
[15] 黄翔超. 考虑制冷剂两相分配不均的微通道蒸发器压降模型[J]. 机械工程学报,2016,52(16):156-161. HUANG Xiangchao. Microchannel evaporator pressure drop model with considering refrigerant maldistribution[J]. Journal of Mechanical Engineering,2016,52(16):156-161.
[16] JONES B J,LEE P S,GARIMELLA S V. Infrared micro-particle image velocimetry measurements and predictions of flow distribution in a microchannel heat sink[J]. International Journal of Heat and Mass Transfer,2008,51(7):1877-1887.
[17] SIDDIQUE A,MEDHI B J,AGRAWAL A,et al. Design of a collector shape for uniform flow distribution in microchannels[J]. Journal of Micromechanics and Microengineering,2017,27:075026.
[18] MAHVI A J,GARIMELLA S. Two-phase flow distribution of saturated refrigerants in microchannel heat exchanger headers[J]. International Journal of Refrigeration,2019,104:84-94.
[19] AVETISSIAN A,PHILIPPOV G,ZAICHIK L I. The effect of turbulence on spontaneously condensing wet-steam flow[J]. Nuclear Engineering and Design,2005,235(10-12):1215-1223.
[20] AVETISSIAN A,PHILIPPOV G,ZAICHIK L I. Effects of turbulence and inlet moisture on two-phase spontaneously condensing flows in transonic nozzles[J]. International Journal of Heat and Mass Transfer,2008,51(17-18):4195-4203.
[21] SPEZIALE C G. On nonlinear K-l and K-ε models of turbulence[J]. Journal of Fluid Mechanics,1987,178:459-475.
[22] GATSKI T,SPEZIALE C G. On explicit algebraic stress models for complex turbulent flows[J]. Journal of Fluid Mechanics,1992,254:59-78.
[23] YAO W,MOREL C. Volumetric interfacial area prediction in upward bubbly two-phase flow[J]. International Journal of Heat and Mass Transfer,2004,47(2):307-328.
[24] ELGHOBASHI S,ABOU-ARAB T W. A two equation turbulence model for two phase flows[J]. Physics of Fluids,1983,26(4):931-938.
[25] TRIPLETT K,GHIAASIAAN S M,ABDEL-KHALIK S,et al. Gas liquid two-phase flow in microchannels Part I:Two-phase flow patterns[J]. International Journal of Multiphase Flow,1999,25(3):377-394.