黏度随温度变化对三角形螺旋夹套内湍流流体流动及换热的影响

doi:10.11949/j.issn.0438-1157.20150392

化工学报 ›› 2015, Vol. 66 ›› Issue (12): 4758-4766.DOI: 10.11949/j.issn.0438-1157.20150392

黏度随温度变化对三角形螺旋夹套内湍流流体流动及换热的影响

王翠华¹, 赵保增¹, 龚斌¹, 寇丽萍¹, 吴剑华^1,2

1 沈阳化工大学能源与动力工程学院, 辽宁沈阳 110142;
2 天津大学化工学院, 天津 300072

收稿日期:2015-03-27 修回日期:2015-09-16 出版日期:2015-12-05 发布日期:2015-12-05
通讯作者: 吴剑华
基金资助:
中央支持地方高校发展专项资金项目(辽财指教[2010] 865号);国家自然科学基金项目(51406125)。

Effects of temperature-dependent viscosity on turbulent flow and heat transfer in jackets with triangular helical ducts

WANG Cuihua¹, ZHAO Baozeng¹, GONG Bin¹, KOU Liping¹, WU Jianhua^1,2

1 School of Energy and Power Engineering, Shenyang University of Chemical Technology, Shenyang 110142, Liaoning, China;
2 School of Chemical Engineering and Technology, Tianjin University, Tianjin 300072, China

Received:2015-03-27 Revised:2015-09-16 Online:2015-12-05 Published:2015-12-05
Supported by:
supported by Special Program for Local Universities Development of Central Finance of China and the National Natural Science Foundation of China (51406125 ).

摘要/Abstract

摘要：

考虑受热流体黏度随温度变化的影响,对三角形螺旋夹套内流体湍流换热进行了数值模拟分析。经与实验结果比对,证明了模拟方法可靠。基于模拟结果重点分析了受热流体黏度变化对流道内流体流动和换热特性的影响,剖析了受热流体的截面平均流动阻力(fRe_m)和平均Nusselt数(Nu_m)沿流动方向的发展特点,并比较了不同流动参数和不同结构参数下流道内受热流体定黏度和变黏度时流体总流动阻力和传热系数的差别。结果表明:考虑流体黏度随温度变化时会明显影响三角形螺旋夹套内流体的流动和换热特性。对比两种流体fRe_m和Nu_m沿流体流动方向的发展过程发现,在早期、中间和后期发展3个阶段中,后期发展阶段中两种流体的发展趋势明显不同;相同来流条件和热边界条件下,与定黏度流体相比,同一横截面上变黏度流体各点的局部流动阻力较小,而局部Nusselt数却较大,因此变黏度流体总的流动阻力较小,而总的传热系数较大;Reynolds数越低,流道量纲一曲率越小,变黏度受热流体的流动和换热性能与定黏度流体流动和换热性能相比差异愈明显,则考虑流体黏度随温度变化对流体流动和传热的影响更为重要。

关键词: 三角形螺旋夹套, 黏度, 换热, 流动

Abstract:

Considering fluid temperature-dependent viscosity, turbulent flow and heat transfer in the jackets with helical ducts were investigated numerically. Comparisons between experimental values and simulated values indicated that the simulation method was reliable. Based on the simulated results, the effects of temperature-dependent viscosity on the characteristics of turbulent flow and heat transfer were studied, variations of the mean flow resistance (fRe_m) and mean Nusselt number (Nu_m) of cross section in the flow direction were analyzed, and the whole flow resistance and the whole Nusselt number of varied viscosity flow were compared with those of constant viscosity flow. The results show that temperature-dependent viscosity affects the features of fluid flow and heat transfer in the jackets to a certain extent. The development of fRe_m and Nu_m along the axial direction is divided into the early, the middle and the later stages. The difference is obvious at the later developing stage between the trends with varied viscosity and constant viscosity. Under the same incoming flow and thermal boundary conditions, compared to those with constant viscosity, the local flow resistance with varied viscosity is lower, the local Nusselt number is larger, so that the whole flow resistance is lower and the whole Nusselt number is larger. Furthermore, with the decrease of the Reynolds number and the dimensionless curvature ratio, differences between the characteristics of flow and heat transfer for varied and constant viscosities are more obvious, so temperature-dependent viscosity is a greater contributing factor to fluid flow and heat transfer.

Key words: jackets with triangular helical ducts, viscosity, heat transfer, fluid flow

中图分类号:

王翠华, 赵保增, 龚斌, 寇丽萍, 吴剑华. 黏度随温度变化对三角形螺旋夹套内湍流流体流动及换热的影响[J]. 化工学报, 2015, 66(12): 4758-4766.

WANG Cuihua, ZHAO Baozeng, GONG Bin, KOU Liping, WU Jianhua. Effects of temperature-dependent viscosity on turbulent flow and heat transfer in jackets with triangular helical ducts[J]. CIESC Journal, 2015, 66(12): 4758-4766.

参考文献 21

[1]	Park J, Ligrani P M. Numerical predictions of heat transfer and fluid flow characteristics for seven different dimpled surfaces in a channel [J]. Num. Heat Transfer A, 2005, 47(3): 209-232.
[2]	Garvin J. Estimate heat transfer and friction in dimple jackets [J]. Chemical Engineering Progress, 2001, 97(4): 73-75.
[3]	Fan Qi (范琦), Yin Xia (尹侠). Numerical simulation of flow and heat transfer and structural optimization of dimple jackets [J]. Chemical Industry and Engineering Progress (化工进展), 2009, 28(1): 31-36.
[4]	Dhotre T, Murthy Z V P. Modeling and dynamic studies of heat transfer cooling of liquid in half-coil jackets [J]. Chem. Eng. J., 2006, 118(3): 183-188.
[5]	Jayakumar N S, Farouq S M. The dynamics of liquid cooling in half-coil jackets [J]. Chemical Product and Process Modeling, 2008, 3(1): 1-16.
[6]	Li Yaxia (李雅侠), Wang Hang (王航), Wu Jianhua (吴剑华). Fully developed laminar flow and heat transfer characteristics in half coil jackets [J]. CIESC Journal (化工学报), 2010, 61(11): 2796-2803.
[7]	Li Yaxia (李雅侠), Hua Bo (华博), Wu Jianhua (吴剑华). Flow characteristics of turbulent fluid in the inner half-coil jackets of an autoclave [J]. The Chinese Journal of Process Engineering (过程工程学报), 2011, 11(6): 913-918.
[8]	Li Yaxia, Wu Jianhua, Zhan Hongren, Wang Cuihua. Fluid flow and heat transfer characteristic of outer and inner half coil jackets [J]. Chinese Journal of Chemical Engineering, 2011, 19(2): 253-261.
[9]	Li Yaxia, Wu Jianhua, Zhang Li, Kou Liping. Comparison of fluid flow and heat transfer behavior in outer and inner half coil jackets and field synergy analysis [J]. Applied Thermal Engineering, 2011, 31(14/15): 3078-3083.
[10]	Wang Cuihua, Liu Shengju, Wu Jianhua, Li Yaxia. Laminar flow and heat transfer characteristics in jackets of triangular flow channels[J]. Chinese Journal of Chemical Engineering, 2013, 21(11): 1224-1231.
[11]	Wang Cuihua, Wu Jianhua, Liu Shengju. Characteristic of turbulent flow in the jackets with triangular helical ducts// The 3rd SREE Conference on Chemical Engineering [C], 2013: 23-28.
[12]	Wang Cuihua (王翠华), Wu Jianhua (吴剑华), Liu Shengju (刘胜举). Simulation on turbulent flow and heat transfer in the triangular helical jacket [J]. The Chinese Journal of Process Engineering (过程工程学报), 2013, 13(4): 580-585.
[13]	Kumar V, Gupta P, Nigam K D P. Fluid flow and heat transfer in curved tubes with temperature-dependent properties [J]. Industrial and Engineering Chemistry Research, 2007, 46(10): 3226-3236.
[14]	Andrade C R, Zaparoli E L. Effects of temperature-dependent viscosity on fully developed laminar forced convection in a curved duct [J]. Int. Communications in Heat and Mass Transfer, 2001, 28(2): 211-220.
[15]	Shin S, Cho Y I, Gringrich W K. Numerical study of laminar heat transfer with temperature dependent fluid viscosity in a 2:1 rectangular duct [J]. International Journal of Heat and Mass Transfer, 1993, 36(18): 4365-4373.
[16]	Chang H S, Chang J W. Laminar heat and fluid flow characteristic with a modified temperature-dependent viscosity model in a rectangular duct [J]. J. Mech. Sci. Tech., 2006, 20(3): 382-390.
[17]	Germano M. The Dean equations extended to a helical pipe flow [J]. J. Fluid Mech., 1989, 203: 289-305.
[18]	Bolinder C J, Sunden B. Flow visualization and LDV measurements of laminar flow in a helical square duct with finite pitch [J]. Exp. Therm. Fluid Sci., 1995, 11(4): 348-363.
[19]	Gui Keting (归柯庭), Wang Jun (王军), Wang Qiuying (王秋颖). Engineering Fluid Mechanics (工程流体力学) [M]. Beijing: Science Press, 2003: 12-14.
[20]	Bondy F, Lippa S. Heat-transfer in agitated vessels [J]. Chemical Engineering, 1983, 90(7): 62-71.
[21]	Wang Fujun (王福军). Computational Fluid Dynamics Analysis (计算流体动力学分析) [M]. Beijing: Tsinghua University Press, 2004: 116-125.

黏度随温度变化对三角形螺旋夹套内湍流流体流动及换热的影响

Effects of temperature-dependent viscosity on turbulent flow and heat transfer in jackets with triangular helical ducts

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