Operation parameters optimization of spacecraft thermal cycling test system based on temperature uniformity and entropy generation

doi:10.11949/j.issn.0438-1157.20160429

Abstract

Abstract:

The temperature uniformity and entropy generation due to heat transfer inside a thermal cycling test chamber are investigated numerically under various operating parameters. Boussinesq approximation and k-ω model are used in the simulation and the result is validated by previous experiment. The result shows that in the range of 4.3×10³ ≤ Re ≤ 8.6×10⁵ and 4.62×10¹³ ≤ Gr ≤ 1.38×10¹⁴, both forced convection and natural convection contribute to the fluid flow and heat transfer. Fluid close to the walls gets heated and rises along the walls due to the buoyancy force while that near the center line accelerates downward to the exit. The temperature at the given height always increases from the center line to the walls. From the top to bottom of the cycling chamber, the temperature increases around the center line while decreases near the walls. The dimensionless standard temperature deviation increases with Reynolds number and changes little with Grashof number. During the mixed convection, the entropy generation due to fluid friction is much smaller than that by heat transfer, and the latter increases with both Reynolds number and Grashof number. In addition, the expressions of wall Nusselt number, dimensionless average temperature, dimensionless temperature standard deviation and dimensionless entropy generation by heat transfer are also provided.

Key words: numerical simulation, convection, heat transfer, temperature uniformity, entropy generation

摘要：

以数值模拟的方法研究了不同运行参数下航天器热循环试验箱内温度均匀度与熵产的变化规律。结果表明，在4.3×10³≤Re≤8.6×10⁵、4.62×10¹³≤Gr≤1.38×10¹⁴范围内，由于强浮升力的作用，壁面附近出现回流区，温度由上往下降低，中轴线附近气体加速下沉，温度由上往下升高。箱内量纲1温度标准偏差随Reynolds数增大而增大，随Grashof数变化不明显；混合对流过程中流动熵产远小于传热熵产，熵产数值随Reynolds数、Grashof数的增大而增大。提出了壁面Nusselt数、试验箱内量纲1平均温度、量纲1温度标准偏差及量纲1传热熵产随Reynolds数、Grashof数变化的关联式。

关键词: 数值模拟, 对流, 传热, 温度均匀度, 熵产

CLC Number:

V416.5

HUANG Yiye, YANG Guang, WU Jingyi. Operation parameters optimization of spacecraft thermal cycling test system based on temperature uniformity and entropy generation[J]. CIESC Journal, 2016, 67(10): 4086-4094.

黄一也, 杨光, 吴静怡. 以最佳温度均匀度和最小熵产为目标的航天器热循环试验系统运行参数优化[J]. 化工学报, 2016, 67(10): 4086-4094.

References 19

[1]	黄本诚. 空间环境工程学[M]. 北京:中国科学技术出版社, 2010:7-10. HUANG B C. Space Environment Engineering[M]. Beijing:Science and Technology of China Press, 2010:7-10.
[2]	黄本诚. KM6载人航天器空间环境试验设备[J]. 中国空间科学技术, 2002, 22(3):1-5. HUANG B C. Space environment test facility for manned spacecraft[J]. Chinese Space Science and Technology, 2002, 22(3):1-5.
[3]	WANG G, ZHAO G, LI H, et al. Analysis of thermal cycling efficiency and optimal design of heating/cooling systems for rapid heat cycle injection molding process[J]. Materials & Design, 2010, 31(7):3426-3441.
[4]	杨光, 吴静怡. 三维动态混合对流过程中的温度均匀性分析及实验验证[J]. 工程热物理学报, 2014, 35(4):730-734. YANG G, WU J Y. Numerical and experimental investigation of the temperature uniformity characteristics of the dynamic mixed convection flow in a three dimensional open cavity[J]. Journal of Engineering Thermophysics, 2014, 35(4):730-734.
[5]	杨光, 吴静怡. 基于小波变换和多元回归的航天器热循环试验系统的温度均匀性分析与预测[J]. 上海交通大学学报, 2014, 48(9):1346-1350. YANG G, WU J Y. Analysis of temperature uniformity in a spacecraft thermal-cycling test system based on wavelet transform and multiple regression[J]. Journal of Shanghai Jiaotong University, 2014, 48(9):1346-1350.
[6]	JACKSON J D, COTTON M A, AXCELL B P. Studies of mixed convection in vertical tubes[J]. International Journal of Heat & Fluid Flow, 1989, 10(1):2-15.
[7]	JACKSON J D, HALL W B. Influences of buoyancy on heat transfer to fluids flowing in vertical tubes under turbulent conditions[J]. Turbulent Forced Convection in Channels and Bundles, 1979, 2:613-640.
[8]	INGHAM D, KEEN D, HEGGS P. Two dimensional combined convection in vertical parallel plate ducts, including situations of flow reversal[J]. International Journal for Numerical Methods in Fluids, 1988, 26(7):1645-1664.
[9]	BERNIER M A, BALIGA B R. Visualization of upward mixed-convection flows in vertical pipes using a thin semitransparent gold-film heater and dye injection[J]. International Journal of Heat and Fluid Flow, 1992, 13:241-249.
[10]	YANG G, WU J Y. Entropy generation in a rectangular channel of buoyancy opposed mixed convection[J]. International Journal of Heat & Mass Transfer, 2015, 86:809-819.
[11]	YANG G, WU J Y, Yan L. Flow reversal and entropy generation due to buoyancy assisted mixed convection in the entrance region of a three dimensional vertical rectangular duct[J]. International Journal of Heat & Mass Transfer, 2013, 67(4):741-751.
[12]	BEJAN A. Entropy generation minimization:the new thermodynamics of finite-size devices and finite-time processes[J]. Journal of Applied Physics, 1996, 79(3):1191-1218.
[13]	BEJAN A. Fundamentals of exergy analysis, entropy generation minimization, and the generation of flow architecture[J]. International Journal of Energy Research, 2002, 26:545-565.
[14]	LIOUA K, OZTOP H F, BORJINI M N, et al. Second law analysis in a three dimensional lid-driven cavity[J]. International Communications in Heat & Mass Transfer, 2011, 38(10):1376-1383.
[15]	OZTOP H F, AL-SALEM K. A review on entropy generation in natural and mixed convection heat transfer for energy systems[J]. Renewable & Sustainable Energy Reviews, 2012, 16(1):911-920.
[16]	孟凡康, 高珊, 闫明慧. 二维方腔自然对流熵产模拟分析[J]. 太阳能学报, 2010, 31(10):1287-1291. MENG F K, GAO S, YAN M H. Numerical analysis on entropy generation of nature convection inside two dimensional square cavity[J]. Acta Energiae Solaris Sinica, 2010, 31(10):1287-1291.
[17]	KOCK F, HERWIG H. Local entropy production in turbulent shear flows:a high-Reynolds number model with wall functions[J]. International Journal of Heat & Mass Transfer, 2004, 47(10):2205-2215.
[18]	KOCK F, HERWIG H. Method and array for introducing temporal correlation in hidden Markov models for speech recognition[J]. International Journal of Heat & Fluid Flow, 2004, 117(117):2698-2699.
[19]	BEJAN A. Convection Heat Transfer[M]. New York:John Wiley & Sons, 2013:204.