圆管束中导流器对其自然对流换热的影响

doi:10.11949/0438-1157.20201399

摘要/Abstract

摘要：

对无限大空间中5根同规格圆管组成的圆管束在管间放置导流器的自然对流换热进行了数值模拟研究。考虑了Ra在10³～10⁴范围内，导流器偏转角为0°～60°，圆管间距为2～4倍圆管直径的自然对流换热，分析了5根圆管的局部Nusselt数（Nu_loc）和平均Nusselt数（Nu_ave）。研究结果表明，导流器对管束结构的自然对流换热影响体现在两方面：一是对导流器下方圆管而言相当于障碍物削弱其换热，二是对导流器上方圆管而言隔绝了下方羽状流的影响，从而增强系统的整体换热。在圆管间距较大时，与无导流器的圆管束相比，C1～C4各圆管换热下降趋势明显放缓，并且从C4、C5圆管换热趋势上升，系统整体换热增强。圆管间距S=2D，Ra=10³，导流器主要起障碍物的作用，削弱C1～C4各圆管换热，导致系统整体换热下降。当导流器偏转角度为45°时系统换热达到最大值，较无导流器时换热最多有着21%的提升。

关键词: 圆管, 导流器, 传热, 自然对流, 数值模拟

Abstract:

For an array composed of 5 cylinders of the same specification in an infinite space, the natural convection heat transfer of diverters placed between the cylinders is numerically simulated. Considering the difference between the natural convection heat transfer when Ra is in the range of 10³—10⁴, the diverter's deflection angle is from 0° to 60°, and the cylinder spacing is from 2 to 4 cylinder diameters. The analysis of the local Nusselt number (Nu_loc) and the average Nusselt number (Nu_ave) of 5 cylinders shows that the natural convection heat transfer of the diverter to the array is reflected in two aspects. First, it is equivalent to an obstacle for the cylinders under the diverter to reduce the heat transfer, the second is to isolate the plume flow from the bottom of the cylinder above the diverter, thereby increasing the overall heat transfer of the array. In the case of large cylinder spacing, compared with the cylinder array without diverter, the heat transfer trend of C1—C4 cylinders has slowed down significantly, and the heat transfer trend of C4,C5 cylinders has increased, and the overall heat exchange of the system has been enhanced. The cylinder spacing S=2D, Ra=10³, the diverter mainly acts as an obstacle, weakening the heat transfer of the C1—C4 cylinders, resulting in a decrease in the overall heat transfer of the array. When the diverter deflection angle is 45°, the heat transfer of the array reaches its maximum value, which is up to 21% higher than that without the diverter.

Key words: cylinder, diverter, heat transfer, natural convection, numerical simulation

中图分类号:

TK 311

王玲玥, 朱进容, 王从乐, 吕辉, 成纯富, 张金业. 圆管束中导流器对其自然对流换热的影响[J]. 化工学报, 2021, 72(S1): 310-317.

WANG Lingyue, ZHU Jinrong, WANG Congle, LYU Hui, CHENG Chunfu, ZHANG Jinye. Influence of diverter in cylinder array on its natural convection heat transfer[J]. CIESC Journal, 2021, 72(S1): 310-317.

图/表 11

图1 物理模型

Fig.1 Sketch of physical model

图2 网格划分

Fig.2 Sketch of mesh generation

表1 不同网格数量下模拟的Nuˉ与文献［29］的对比

Table 1 Comparisons of simulated Nusselt number Nuˉ for different grids with experimental result of Ref. ［29］

网格数	$\overset{ˉ}{N u}$
154184	9.119
218802	9.813
310166	9.998
412656	9.994
文献^[29]	10.109

表1 不同网格数量下模拟的Nuˉ与文献［29］的对比

Table 1 Comparisons of simulated Nusselt number Nuˉ for different grids with experimental result of Ref. ［29］

网格数	$\overset{ˉ}{N u}$
154184	9.119
218802	9.813
310166	9.998
412656	9.994
文献^[29]	10.109

表2 单圆管局部Nuloc与已有结果的对比

Table 2 Comparison of Nuloc for single cylinder and existing results

Ra		Nu_loc
Ra		θ=0°	θ=30°	θ=60°	θ=90°	θ=120°	θ=150°	θ=180°
10³	本文	3.822	3.795	3.687	3.501	2.894	1.974	1.258
	文献^[28]	3.798	3.755	3.640	3.376	2.841	1.958	1.210
	文献^[6]	3.813	3.772	3.640	3.374	2.866	1.975	1.218
10⁴	本文	6.159	6.138	5.869	5.561	4.903	3.326	1.577
	文献^[28]	5.986	5.931	5.756	5.406	4.716	3.293	1.532
	文献^[6]	5.995	5.935	5.750	5.410	4.764	3.308	1.534
10⁵	本文	9.715	9.652	9.318	8.791	7.992	5.833	2.107
	文献^[28]	9.694	9.595	9.297	8.749	7.871	5.848	1.989
	文献^[6]	9.675	9.557	9.278	8.765	7.946	5.891	1.987

图3 竖排5根圆管束各圆管的Nuave的仿真结果与已有试验结果对比

Fig.3 Comparison of simulation results of Nuave of each cylinder in a vertical array of 5 cylinders and existing experimental results

图4 导流器置于不同偏转角度时的流线

Fig.4 Streamline diagram when diverters are placed at different deflection angle

图5 导流器置于不同偏转角度时的温度图

Fig.5 Temperature diagram when diverters are placed at different deflection angles

图6 导流器置于不同偏转角度圆管束系统平均Nusselt数（Nuarray）和系统中各圆管Nuave

Fig.6 Nuarrayand Nuave of each cylinder in array when diverters are placed at different deflection angles

图7 圆管间距为S=2D~4D的温度图和流线图

Fig.7 Temperature diagram and streamline diagram with a cylinder spacing of S=2D ~4D

图8 圆管束系统中各圆管Nuave

Fig.8 Nuave of each cylinder in array

图9 圆管束系统Nuarray

Fig.9 Average Nu number of cylinders array

参考文献 29

1	Chung B J, Eoh J H, Heo J H. Visualization of natural convection heat transfer on horizontal cylinders [J]. Heat and Mass Transfer, 2011, 47(11): 1445-1452.
2	Seo Y M, Mun G S, Park Y G, et al. Two-dimensional flow instability induced by natural convection in a square enclosure with four inner cylinders (Ⅱ): Effect of various positions of inner cylinders [J]. International Journal of Heat and Mass Transfer, 2017, 113: 1319-1331.
3	Moreno S, Hinojosa J F, Hernández-López I, et al. Numerical and experimental study of heat transfer in a cubic cavity with a PCM in a vertical heated wall [J]. Applied Thermal Engineering, 2020, 178: 115647.
4	Ghalambaz M, Mehryan S A M, Alsabery A I, et al. Controlling the natural convection flow through a flexible baffle in an L-shaped enclosure [J]. Meccanica, 2020, 55(8): 1561-1584.
5	张敏, 陶锴, 晏刚. 含内热源的梯形腔自然对流换热数值模拟 [J]. 化工学报, 2011, 62(6): 1543-1548.
	Zhang M, Tao K, Yan G. Numerical simulation of natural convection in trapezoidal enclosures with discrete heater [J]. CIESC Journal, 2011, 62(6): 1543-1548.
6	Saitoh T, Sajiki T, Maruhara K. Bench mark solutions to natural convection heat transfer problem around a horizontal circular cylinder [J]. International Journal of Heat and Mass Transfer, 1993, 36(5): 1251-1259.
7	He Z H, Zhu J R, Zhang J Y, et al. Natural convection heat transfer from a horizontal cylinder using holographic interferometry [J]. Heat Transfer — Asian Research, 2019, 48(1): 115-126.
8	石宏岩, 刘捷, 卢文强. 水平紧密接触品字形三圆管自然对流换热的数值模拟[J]. 中国科学院大学学报, 2018, 35(5): 595-601.
	Shi H Y, Liu J, Lu W Q. Numerical simulation of laminar natural convection heat transfer from three horizontal attached cylinders [J]. Journal of University of Chinese Academy of Sciences, 2018, 35(5): 595-601.
9	Liu J, Liu H, Zhen Q, et al. Numerical investigation of the laminar natural convection heat transfer from two horizontally attached horizontal cylinders [J]. International Journal of Heat and Mass Transfer, 2017, 104: 517-532.
10	Ashjaee M, Yazdani S, Bigham S, et al. Experimental and numerical investigation on free convection from a horizontal cylinder located above an adiabatic surface [J]. Heat Transfer Engineering, 2012, 33(3): 213-224.
11	Kitamura K, Mitsuishi A, Suzuki T, et al. Fluid flow and heat transfer of natural convection induced around a vertical row of heated horizontal cylinders [J]. International Journal of Heat and Mass Transfer, 2016, 92: 414-429.
12	Elsherbiny S M, Teamah M A, Moussa A R. Natural convection heat transfer from an isothermal horizontal square cylinder [J]. Alexandria Engineering Journal, 2017, 56(1): 181-187.
13	朱进容, 代金梅, 程晓敏, 等. 基于全息术的水平偏置椭圆管自然对流换热[J]. 化工学报, 2016, 67(4): 1145-1149.
	Zhu J R, Dai J M, Cheng X M, et al. Natural convection heat transfer from horizontal offset elliptic tube based on holographic interferometry [J]. CIESC Journal, 2016, 67(4): 1145-1149.
14	Herráez J V, Belda R. A study of free convection in air around horizontal cylinders of different diameters based on holographic interferometry. Temperature field equations and heat transfer coefficients [J]. International Journal of Thermal Sciences, 2002, 41(3): 261-267.
15	Ashjaee M, Yousefi T, Amiri M. Free convection heat transfer from a confined horizontal elliptic cylinder [J]. Heat Transfer Engineering, 2006, 27(10): 116-124.
16	Narayan S, Singh A K, Srivastava A. Interferometric study of natural convection heat transfer phenomena around array of heated cylinders [J]. International Journal of Heat and Mass Transfer, 2017, 109: 278-292.
17	Yousefi T, Ashjaee M. Experimental study of natural convection heat transfer from vertical array of isothermal horizontal elliptic cylinders [J]. Experimental Thermal and Fluid Science, 2007, 32(1): 240-248.
18	Naylor D, Lai B Y. Experimental study of natural convection in a window with a between-panes Venetian blind [J]. Experimental Heat Transfer, 2007, 20(1): 1-17.
19	Najafian Ashrafi Z, Ashjaee M. Temperature field measurement of an array of laminar premixed slot flame Jets using Mach-Zehnder interferometry [J]. Optics and Lasers in Engineering, 2015, 68: 194-202.
20	朱进容, 吕伟, 周怀春. 横向大剪切干涉应用于水平圆管自然对流换热 [J]. 化工学报, 2012, 63(10): 3034-3039.
	Zhu J R, Lü W, Zhou H C. Natural convection heat transfer of horizontal cylinder with lateral shearing interferometry [J]. CIESC Journal, 2012, 63(10): 3034-3039.
21	Qi C B, Zheng S, Zhou H C. Experimental investigation on gas-phase temperature of axisymmetric ethylene flames by large lateral shearing interferometry [J]. International Journal of Thermal Sciences, 2017, 115: 104-111.
22	Zeitoun O, Ali M. Numerical investigation of natural convection around isothermal horizontal rectangular ducts [J]. Numerical Heat Transfer, Part A: Applications, 2006, 50(2): 189-204.
23	Khodary K, Bhattacharyya T K. Optimum natural convection from square cylinder in vertical channel [J]. International Journal of Heat and Fluid Flow, 2006, 27(1): 167-180.
24	Liao C C, Lin C A. Influences of a confined elliptic cylinder at different aspect ratios and inclinations on the laminar natural and mixed convection flows [J]. International Journal of Heat and Mass Transfer, 2012, 55(23/24): 6638-6650.
25	Liu J, Liu H, Zhen Q, et al. Laminar natural convection heat transfer from a pair of attached horizontal cylinders set in a vertical array [J]. Applied Thermal Engineering, 2017, 115: 1004-1019.
26	Sebastian G, Shine S R. Natural convection from horizontal heated cylinder with and without horizontal confinement [J]. International Journal of Heat and Mass Transfer, 2015, 82: 325-334.
27	de Kumar A, Dalal A. A numerical study of natural convection around a square, horizontal, heated cylinder placed in an enclosure [J]. International Journal of Heat and Mass Transfer, 2006, 49(23/24): 4608-4623.
28	Corcione M. Correlating equations for free convection heat transfer from horizontal isothermal cylinders set in a vertical array [J]. International Journal of Heat and Mass Transfer, 2005, 48(17): 3660-3673.
29	Ashjaee M, Yousefi T, Farahmand S, et al. Enhancement of free convection heat transfer from a vertical array of isothermal cylinders by flow diverters [J]. Heat Transfer Engineering, 2009, 30(3): 197-206.

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