RKPM numerical simulation for photothermal characteristic of n-octadecane with melting process

doi:10.11949/j.issn.0438-1157.20150823

Abstract

Abstract:

To establish coupling algorithm of radiation and conduction for one-dimensional translucent material with phase change, to understand the melting process of n-octadecane with infrared irradiation source, and to obtain the temperature distribution in the material, the modified equivalent heat capacity method is used for latent heat absorption and release with transient heat transfer, the gradient refractive index method is used for radiative transfer in variable refractive index medium, and a calculation method is established for phase change process of coupling radiation and conduction of one-dimensional semitransparent materials based on the reproducing kernel particle method (RKPM). The temperature response characteristics of n-octadecane with phase change were measured experimentally under the infrared radiation heating condition to verify the accuracy of numerical method. The results show that numerical simulation values match the experimental values well both in the temperature level and time characteristics, indicating that the method has very good accuracy. The selection of convective heat transfer coefficient has a certain influence on the simulation results.

Key words: numerical simulation, radiation, reproducing kernel particle method, phase change, n-octadecane, experimental validation

摘要：

建立求解一维半透明材料相变过程的辐射导热耦合计算方法,了解正十八烷(n-octadecane)在辐射源作用下的相变熔化过程,获得材料内部温度分布,验证数值方法准确性。基于无网格RKMP方法,采用修正等效热容法处理相变潜热的吸收与释放,利用梯度折射率的方法处理变折射率介质内的辐射传输问题。实验测量了n-octadecane在红外辐照加热条件下的熔化过程温度响应特性。结果表明数值模拟值和实验值在温度水平和时间特性两方面都符合良好,验证了计算方法具有良好的精度。

关键词: 数值模拟, 辐射, RKPM, 相变, 正十八烷, 实验验证

CLC Number:

TK121

TANG Jiadong, HE Zhihong, MU Lei, DONG Shikui. RKPM numerical simulation for photothermal characteristic of n-octadecane with melting process[J]. CIESC Journal, 2015, 66(12): 4767-4773.

唐佳东, 贺志宏, 穆磊, 董士奎. 基于RKPM的n-octadecane熔化过程光热特性数值模拟与验证[J]. 化工学报, 2015, 66(12): 4767-4773.

References 21

[1]	Guo Haifeng (果海凤). Heat transfer and energy conservation research on the phase change heat storage technology in greenhouse [D]. Beijing: Beijing University of Technology, 2008.
[2]	Zhuang Chunlong (庄春龙). Solar energy heating study on the light weight building made by phase change material wall in the Qingzang altiplano north area [D]. Chongqing: Chongqing University, 2011.
[3]	Karlessi T, Santamouris M, Synnefa A, et al. Development and testing of PCM doped cool colored coatings to mitigate urban heat island and cool buildings [J]. Building and Environment, 2011, 46: 570-576.
[4]	Ismail K A R, Henríquez J R. Thermally effective windows with moving phase change material curtains [J]. Applied Thermal Engineering, 2001, 21: 1909-1923.
[5]	Ismail K A R, Henríquez J R. Parametric study on composite and PCM glass systems [J]. Energy Conversion and Management, 2002, 43: 973-993.
[6]	Wang Qingqing(王青青). Heat transfer characteristics of phase change wallboards and windows[D]. Harbin: Harbin Institute of Technology, 2012.
[7]	Peng Huaqiao(彭华乔), Xia Zuxi(夏祖西), Su Zhengliang(苏正良), Li Wenyan(李文艳). The application of infrared heating technology in de-icing an airplane [J]. Infrared Technology(红外技术), 2008, 30(6): 368-370.
[8]	Chen Guang(陈光). The design of infrared heating system for deicing vehicle and numerical simulation of heating process[D]. Dalian: Dalian University of Technology, 2003.
[9]	Wang S X, Li Y, Hu J Y, Tokura H, Song Q W. Effect of phase-change material on energy consumption of intelligent thermal-protective clothing [J]. Polymer Testing, 2006, 25: 580-587.
[10]	Li Yi, Zhu Qingyong. A model of heat and moisture transfer in porous textiles with phase change materials [J]. Textile Research Journal, 2004, 74(5): 447-457.
[11]	Xu Jingyu(徐静宇). The effect of layers configuration on thermal buffer action of PCM protective clothing[D]. Suzhou: Soochow University, 2014.
[12]	Lai Yanhua(赖艳华), Wu Tao(吴涛), Wei Lulu(魏露露), Dong Zhen(董震), Lü Mingxin(吕明新). Thermal performance of electronic components based on phase change materials [J]. CIESC Journal(化工学报), 2014, 65(S1): 157-161.
[13]	Yang Jialin(杨佳霖), Du Xiaoze(杜小泽), Yang Lijun(杨立军), Yang Yongping(杨勇平). Visualized experiment on dynamic thermal behavior of phase change material in metal foam [J]. CIESC Journal (化工学报), 2015, 66(2): 497-503.
[14]	Zhu Dongsheng(朱冬生), Liu Shijie(刘世杰), Xu Ting(徐婷), Zhang Xiurong(张秀荣). Study on performance of graphite/MA composite phase change material [J]. Acta Energiae Solaris Sinica(太阳能学报), 2014, 35(5): 819-824.
[15]	Mu Lei, He Zhihong, Dong Shikui. Reproducing kernel particle method for radiative heat transfer in 1D participating media [J]. Mathetatical Problems in Engineering, 2015,2015: 1-11.
[16]	Liu Linhua, Tan Jianyu. Meshless local Petrov-Galerkin method for solving radiative transfer equation [J]. J. Thermophys. Heat Tr., 2006, 20(1): 150-154.
[17]	Zhang Yong, Yi Hongliang, Tan Heping. Natural element method for radiative heat transfer in two-dimensional semitransparent medium [J]. Int. J. Heat Mass Tran., 2013, 56(1/2): 411-423.
[18]	Mu Lei(穆磊), He Zhihong(贺志宏), Ma Yu(马宇), Dong Shikui(董士奎). The application for reproducing kernel particle method in radiative transfer meshless calculation [J]. Journal of Engineering Thermophysics(工程热物理学报), 2014, 35(11): 2248-2251.
[19]	Zhou Yetao(周业涛), Guan Zhenqun(关振群), Gu Yuanxian(顾元宪). Equivalent heat capacity method for solution of heat transfer with phase change [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2004, 55(9): 1428-1433.
[20]	Liu W K, Jun S, Zhang Y F. Reproducing kernel particle methods [J]. International Journal for Numerical Methods in Fluids, 1995, 20(8): 1081-1106.
[21]	Diaz L A, Viskanta R. Experiments and analysis on the melting of a semitransparent material by radiation [J]. Wärme-und Stoffübertragung, 1986, 20(4): 311-321.