DMLS微型换热器内纳米粒子浓度对Al2O3/R141b流动沸腾压降的影响

doi:10.11949/j.issn.0438-1157.20160634

摘要/Abstract

摘要：

为探究纳米粒子浓度对纳米流体制冷剂在微细通道中流动沸腾气液两相压降影响，运用超声波振动法制备质量分数为0.05%、0.1%、0.2%、0.3%、0.4%均匀、稳定的Al₂O₃/R141b纳米流体制冷剂，在直接激光烧结（DMLS）微型换热器中，设计系统压力为176 kPa，纳米流体制冷剂入口温度为40℃，在热通量21.2~38.2 kW·m^-2和质量流率183.13~457.83 kg·m^-2·s^-1工况下，研究纳米粒子浓度对Al₂O₃/R141b纳米流体制冷剂流动沸腾气液两相压降影响。研究结果表明：纳米粒子浓度对纳米流体制冷剂在微细通道中流动沸腾气液两相压降有显著影响，气液两相压降随纳米流体制冷剂的纳米粒子浓度增加而减少，在纯制冷剂中R141b加入纳米粒子Al₂O₃，不同质量分数的纳米流体制冷剂流动沸腾气液两相压降降低5.5%~32.6%；通过SEM和表面静态接触角测试方法，发现纳米流体制冷剂沸腾气液两相压降随质量分数增加而减少的原因是纳米颗粒沉积在通道表面，增加了微通道表面的润湿性；对比国际上3种比较经典流动沸腾两相压降模型，并基于Qu-Mudawar关联式和Zhang关联式进行修正，得出两相压降结果的85%数据点位于修正后的关联式模型值的±15%范围之内，同时实验结果与修正后的模型结果偏差MAE值为11.7%，说明修正后关联式能有效预测本工况下实验值。

关键词: 微通道, 烧结, 纳米粒子, 浓度, 气液两相, 压降

Abstract:

Uniform and stable nanorefrigerant coolants of 0.05%-0.4% Al₂O₃/R141b (mass fraction) were prepared by ultrasonic vibration and used to investigate nanoparticle concentration on pressure drop of gas-liquid two-phase boiling flow of a nanorefrigerant in micro channels. A micro heat exchanger was fabricated by direct metal laser sintering (DMLS) with designed capacity of system pressure at 176 kPa and inlet temperature at 40℃. At conditions of heat flux 21.2-38.2 kW·m^-2 and mass flow rate 183.13-457.83 kg·m^-2·s^-1, the experimental results show that the nanoparticle concentration had significant impact on pressure drop of Al₂O₃/R141b nanoparticle coolant boiling flow in micro channels and the pressure drop decreased with the increase of nanoparticle concentration. After added Al₂O₃ nanoparticles to pure R141b coolant, pressure drop of the pure refrigerant in micro channels was reduced by 5.5%-32.6% depending on mass faction of nanoparticles. Scanning electron microscopy (SEM) and static contact angle measurement revealed that deposition of some Al₂O₃ nanoparticles on the microchannel surface increased surface wettability, which might lower pressure drop of Al₂O₃/R141b upon increase of nanoparticle concentration. Considered three classic pressure drop models and correlations of Qu-Mudawar's and Zhang's for gas-liquid two-phase boiling flow, a revised correlation was developed that 85% of the experimental data points on pressure drop were fallen within a ±15% range of model calculation. The revised correlation can effectively predict the experimental results under these conditions as supported by small MAE number of 11.7%, which was relative deviation between experimental results and revised model predictions.

Key words: microchannel, sintering, nanoparticle, concentration, gas-liquid two-phase, pressure drop

中图分类号:

TK124

周建阳, 罗小平, 谢鸣宇, 邓聪. DMLS微型换热器内纳米粒子浓度对Al₂O₃/R141b流动沸腾压降的影响[J]. 化工学报, 2016, 67(11): 4587-4598.

ZHOU Jianyang, LUO Xiaoping, XIE Mingyu, DENG Cong. Influence of nanoparticle concentration on pressure drop of Al₂O₃/R141b boiling flow in micro heat exchanger by direct metal laser sintering[J]. CIESC Journal, 2016, 67(11): 4587-4598.

参考文献 29

[1]	ASADIA M, XIE G, SUNDEN B, et al. A review of heat transfer and pressure drop characteristics of single and two-phase microchannels[J]. International Journal of Heat and Mass Transfer, 2014, 79:34-53.
[2]	RAPOLU P, SON S Y. Capillary effects on two-phase flow resistance in micro-channels[C]//ASME International Mechanical Engineering Congress and Exposition. NewYork:ASME, 2008:1039-1045.
[3]	YU D, CHOI C, KIM M H. The pressure drop and dynamic contact angle of motion of triple-lines in hydrophobic microchannels[J]. Experimental Thermal and Fluid Science, 2012, 39:60-70.
[4]	CHOI S U S, EASTMAN J A. Enhancing thermal conductivity of fluids with nanoparticles[J]. ASME International Mechanical Engineering Congress & Exposition, 1995, 11:99-105.
[5]	BI S, GUO K, LIU Z, et al. Performance of a domestic refrigerator using TiO2-R600a nano-refrigerant as working fluid[J]. Energy Conversion and Management, 2011, 52(1):733-737.
[6]	SHAHI M, MAHMOUDI A H, RAOUF A H. Entropy generation due to natural convection cooling of a nanofluid[J]. International Communications in Heat and Mass Transfer, 2011, 38(7):972-983.
[7]	MOHAMMED H A, GUNNASEGARAN P, SHUAIB N H. The impact of various nanofluid types on triangular microchannels heat sink cooling performance[J]. International Communications in Heat and Mass Transfer, 2011, 38(6):767-773.
[8]	PARVIN S, ALIM M A, HOSSAIN N F. Prandtl number effect on cooling performance of a heated cylinder in an enclosure filled with nanofluid[J]. International Communications in Heat and Mass Transfer, 2012, 39(8):1220-1225.
[9]	LEE S W, KIM K M, BANG I C. Study on flow boiling critical heat flux enhancement of graphene oxide/water nanofluid[J]. International Journal of Heat and Mass Transfer, 2013, 65:348-356.
[10]	VAFAEI S, WEN D. Critical heat flux of nanofluids inside a single microchannel:experiments and correlations[J]. Chemical Engineering Research and Design, 2014, 92(11):2339-2351.
[11]	KAMATCHI R, VENKATACHALAPATHY S. Parametric study of pool boiling heat transfer with nanofluids for the enhancement of critical heat flux:a review[J]. International Journal of Thermal Sciences, 2015, 87:228-240.
[12]	SAIDUR R, KAZI S N, HOSSAIN M S, et al. A review on the performance of nanoparticles suspended with refrigerants and lubricating oils in refrigeration systems[J]. Renewable and Sustainable Energy Reviews, 2011, 15(1):310-323.
[13]	AZIZI Z, ALAMDARI A, MALAYERI M R. Convective heat transfer of Cu-water nanofluid in a cylindrical microchannel heat sink[J]. Energy Conversion and Management, 2015, 101:515-524.
[14]	HUSSIEN A A, ABDULLAH M Z, AL-NIMR M A. Single-phase heat transfer enhancement in micro/minichannels using nanofluids:theory and applications[J]. Applied Energy, 2016, 164:733-755.
[15]	EDALATPOUR M, MOGHADAM M C, NIAZMAND H, et al. Nanofluid flow and heat transfer in a microchannel with longitudinal vortex generators:two-phase numerical simulation[J]. Applied Thermal Engineering, 2016, 100:179-189.
[16]	VAFAEI S, WEN D. Flow boiling heat transfer of alumina nanofluids in single microchannels and the roles of nanoparticles[J]. Journal of Nanoparticle Research, 2010, 13:1063-1073.
[17]	ZHANG H, SHAO S, XU H, et al. Heat transfer and flow features of Al2O3-water nanofluids flowing through a circular microchannel-experimental results and correlations[J]. Applied Thermal Engineering, 2013, 61(2):86-92.
[18]	ZHAO G, JIAN Y, LI F. Streaming potential and heat transfer of nanofluids in microchannels in the presence of magnetic field[J]. Journal of Magnetism and Magnetic Materials, 2016, 407:75-82.
[19]	BARZEGARIAN R, MORAVEJI M K. ALIREZA A. Experimental investigation on heat transfer characteristics and pressure drop of BPHE (brazed plate heat exchanger) using TiO2-water nanofluid[J]. Experimental Thermal and Fluid Science, 2016, 74:11-18.
[20]	KANDLIKAR S, GRANDE W. Evolution of microchannel flow passages-thermohydraulic performance and fabriction technology[J]. Heat Transfer Engineering, 2003, 24:3-17.
[21]	ALAM T, LEE P S, YAP C R, et al. Experimental investigation of local flow boiling heat transfer and pressure drop characteristics in microgap channel[J]. International Journal of Heat and Mass Transfer, 2012, 42:164-174.
[22]	LEE J, MUDAWAR I. Two-phase flow in high heat flux microchannel heat sink for refrigeration cooling applications (Ⅰ):Pressure drop characteristics[J]. International Journal of Heat and Mass Transfer, 2005, 48:928-940.
[23]	PARK C Y, JANG Y, KIM B, et al. Flow boiling heat transfer coefficients and pressure drop of FC-72 in microchannels[J]. International Journal of Multiphase Flow, 2012, 39:45-54.
[24]	PHAN H T, CANEY N. MARTY P, et al. Flow boiling of water in a minichannel:the effects of surface wettability on two-phase pressure drop[J]. Applied Thermal Engineering, 2011, 31(11):1894-1905.
[25]	TANG X, ZHAO Y H, DIAO Y H. Experimental investigation of the nucleate pool boiling heat transfer characteristics of Al2O3-R141b nanofluids on a horizontal plate[J]. Experimental Thermal and Fluid Science, 2014, 52:88-96.
[26]	LOCKHART R W, MARTINELLI R C. Proposed correlation of data for isothermal two-phase two-component flow in pipes[J]. Chem. Eng. Prog., 1949, 45:39-48.
[27]	MISHIMA K, HIBIKI T. Some characteristics of air-water two-phase flow in small diameter vertical tubes[J]. International Journal of Multiphase Flow, 1996, 22:703-712.
[28]	WEI L Q, MUDAWAR I. Measurement and prediction of pressure drop in two-phase micro-channel heat sinks[J]. International Journal of Heat and Mass Transfer, 2003, 46:2737-2753.
[29]	ZHANG W, HIBIKI T, MISHIMA K. Correlations of two-phase frictional pressure drop and void fraction in mini-channel[J]. International Journal of Heat and Mass Transfer, 2010, 53:453-465.

DMLS微型换热器内纳米粒子浓度对Al₂O₃/R141b流动沸腾压降的影响

Influence of nanoparticle concentration on pressure drop of Al₂O₃/R141b boiling flow in micro heat exchanger by direct metal laser sintering

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献 29

相关文章 15

编辑推荐

Metrics

本文评价

[1]	江河, 袁俊飞, 王林, 邢谷雨. 均流腔结构对微细通道内相变流动特性影响的实验研究[J]. 化工学报, 2023, 74(S1): 235-244.
[2]	袁佳琦, 刘政, 黄锐, 张乐福, 贺登辉. 泡状入流条件下旋流泵能量转换特性研究[J]. 化工学报, 2023, 74(9): 3807-3820.
[3]	仪显亨, 周骛, 蔡小舒, 蔡天意. 光纤后向动态光散射测量纳米颗粒的浓度适用范围研究[J]. 化工学报, 2023, 74(8): 3320-3328.
[4]	曾如宾, 沈中杰, 梁钦锋, 许建良, 代正华, 刘海峰. 基于分子动力学模拟的Fe₂O₃纳米颗粒烧结机制研究[J]. 化工学报, 2023, 74(8): 3353-3365.
[5]	刘文竹, 云和明, 王宝雪, 胡明哲, 仲崇龙. 基于场协同和耗散的微通道拓扑优化研究[J]. 化工学报, 2023, 74(8): 3329-3341.
[6]	邢雷, 苗春雨, 蒋明虎, 赵立新, 李新亚. 井下微型气液旋流分离器优化设计与性能分析[J]. 化工学报, 2023, 74(8): 3394-3406.
[7]	高燕, 伍鹏, 尚超, 胡泽君, 陈晓东. 基于双流体喷嘴的磁性琼脂糖微球的制备及其蛋白吸附性能探究[J]. 化工学报, 2023, 74(8): 3457-3471.
[8]	高金明, 郭玉娇, 鄂承林, 卢春喜. 一种封闭罩内顺流多旋臂气液分离器的分离特性研究[J]. 化工学报, 2023, 74(7): 2957-2966.
[9]	刘起超, 周云龙, 陈聪. 起伏振动垂直上升管气液两相流截面含气率分析与计算[J]. 化工学报, 2023, 74(6): 2391-2403.
[10]	张希庆, 王琰婷, 徐彦红, 常淑玲, 孙婷婷, 薛定, 张立红. Mg量影响的纳米片负载Pt-In催化异丁烷脱氢性能[J]. 化工学报, 2023, 74(6): 2427-2435.
[11]	李勇, 高佳琦, 杜超, 赵亚丽, 李伯琼, 申倩倩, 贾虎生, 薛晋波. Ni@C@TiO₂核壳双重异质结的构筑及光热催化分解水产氢[J]. 化工学报, 2023, 74(6): 2458-2467.
[12]	江锦波, 彭新, 许文烜, 门日秀, 刘畅, 彭旭东. 泵出型螺旋槽油气密封泄漏特性及参数影响研究[J]. 化工学报, 2023, 74(6): 2538-2554.
[13]	董鑫, 单永瑞, 刘易诺, 冯颖, 张建伟. 非牛顿流体气泡羽流涡特性数值模拟研究[J]. 化工学报, 2023, 74(5): 1950-1964.
[14]	葛泽峰, 吴雨青, 曾名迅, 查振婷, 马宇娜, 侯增辉, 张会岩. 灰化学成分对生物质气化特性的影响规律[J]. 化工学报, 2023, 74(5): 2136-2146.
[15]	许文烜, 江锦波, 彭新, 门日秀, 刘畅, 彭旭东. 宽速域三种典型型槽油气密封泄漏与成膜特性对比研究[J]. 化工学报, 2023, 74(4): 1660-1679.