Simulation of falling film flow and heat transfer at shell-side of coil-wound heat exchanger

doi:10.11949/j.issn.0438-1157.20150841

Abstract

Abstract:

The objective of this paper is to develop a numerical model to predict the two-phase flow,heat transfer and mass transfer at shell-side of coil-wound heat exchangers(CWHEs),which can predict the performance of heat exchangers and optimize the structure of CWHE.To achieve this goal,the mechanism of the status of shell-side two-phase flow should be analyzed.Then,a model for simulating flow pattern,including the droplet flow,the column flow and the sheet flow,is developed by employing the volume of fluid-continuous surface force method;the mass transfer model is developed and mass transfer rate can be predicted on tube surface and liquid-gas interface;then the latent heat during evaporation and condensation can be calculated based on the mass transfer rates;the forces and the heat and mass transfer rates are introduced into the control equations as the source terms.The proposed model is validated by the experimental data from the existing references.There is good agreement between experimental data and predictions.The validation results show that 89% of the predicted data can agree with the experimental data within a deviation of ±25%. The heat and mass transfer coefficients obtained by the model are also analyzed.

Key words: coil-wound heat exchanger, two-phase flow, falling film, phase change, numerical model

摘要：

为了定量描述绕管式换热器壳侧降膜蒸发特性并进而优化换热器结构,建立了绕管式换热器壳侧降膜蒸发过程流动与传热的数值模型。首先对降膜流动过程中流型变化和传热传质机理进行分析;通过对降膜流动过程液膜所受表面张力、重力和剪切力的计算,实现层状流、柱状流和滴状流等不同流型的模拟;通过管壁面和气液交界面的组分守恒建立降膜蒸发过程的传质子模型,并基于传质速率计算得出潜热传热速率。将数值模拟结果与已有文献中实验数据进行了对比,结果显示89%的模拟数据与实验数据偏差不超过25%;模拟结果与实验数据吻合较好。基于提出的模型,对不同工况下的绕管式换热器壳侧降膜蒸发传热传质规律进行了分析。

关键词: 绕管式换热器, 两相流, 液膜, 相变, 数值模拟

CLC Number:

TK124

LI Jianrui, CHEN Jie, PU Hui, LI Endao, DING Guoliang, ZHUANG Dawei, HU Haitao. Simulation of falling film flow and heat transfer at shell-side of coil-wound heat exchanger[J]. CIESC Journal, 2015, 66(S2): 40-49.

李剑锐, 陈杰, 浦晖, 李恩道, 丁国良, 庄大伟, 胡海涛. 绕管式换热器壳侧降膜流动和相变传热的数值模拟[J]. 化工学报, 2015, 66(S2): 40-49.

References 33

[1]	Shukri T.LNG technology selection[J].Hydrocarbon Engineering,2004,9(2):71-76.
[2]	Neeraas B O.Condensation of hydrocarbon mixtures in coil-wound LNG heat exchangers,tube-side heat transfer and pressure drop[D].Trondheim:Norwegian Institute of Technology,1993.
[3]	Pacio J C,Dorao C A.A review on heat exchanger thermal hydraulic models for cryogenic applications[J]. Cryogenics,2011,51(7):366-379.
[4]	Linde A G.Aluminium plate-fin heat exchangers[R].
[5]	Crawford D B,Eschenbrenner G P.Heat transfer equipment for LNG projects[J].Chem.Eng.Process,1972,68(9):62-70.
[6]	McKeever J,Pillarella M,Bower R.An ever evolving tech-nology[J].LNG Industry,2008:44-49.
[7]	Fredheim A O.Thermal design of coil-wound LNG heat exchangers shell-side heat transfer and pressure drop[D].Trondheim:University of Trondheim,1994.
[8]	Shokouhmand H,Salimpour M R,Akhavan-Behabadi M A.Experimental investigation of shell and coiled tube heat exchangers using Wilson plots[J].International Communi-cations in Heat and Mass Transfer,2008,35(1):84-92.
[9]	Aunan B.Shell-side heat transfer and pressure drop in coil-wound LNG heat exchangers,laboratory measurements and modeling[D].Trondheim:Norwegian University of Science and Technology,2000.
[10]	Neeraas B O,Fredheim A O,Aunan B.Experimental shell-side heat transfer and pressure drop in gas flow for spiral-wound LNG heat exchanger[J].International Journal of Heat and Mass Transfer,2004,47(2):353-361.
[11]	Neeraas B O,Fredheim A O,Aunan B.Experimental data and model for heat transfer,in liquid falling film flow on shell-side,for spiral-wound LNG heat exchanger[J].International Journal of Heat and Mass Transfer,2004,47(14):3565-3572.
[12]	Lu Xing,Du Xueping,Zeng Min,Zhang Sen,Wang Qiuwang.Shell-side thermal-hydraulic performances of multi-layer spiral-wound heat exchangers under different wall thermal boundary conditions[J].Applied Thermal Engineering,2014,70(2):1216-1227.
[13]	Killion J D,Garimella S.Simulation of pendant droplets and falling films in horizontal tube absorbers[J].Journal of Heat Transfer,2004,126(6):1003-1013.
[14]	Lei Xianliang(雷贤良),Li Huixiong(李会雄),Yan Libo(颜利波),et al.Numerical investigation on the offset characteristics of falling liquid columns over horizontal tubes under the interaction of inter-tube gas flows[J].Journal of Engineering Thermophysics(工程热物理学报),2010,31(11):1875-1878.
[15]	Wang Xiaofei(王小飞),He Maogang(何茂刚),Zhang Ying(张颖).Numerical simulation of the liquid flowing outside the tube of the horizontal-tube falling film evaporator[J].Journal of Engineering Thermophysics(工程热物理学报),2008,29(8):1347-1350.
[16]	Qiu Qinggang(邱庆刚),Chen Jinbo(陈金波).Nume-rical simulation of film formation on horizontal-tube falling film evaporators[J].Journal of Chinese Society of Power Engineering(动力工程学报),2011,31(5):357-361.
[17]	Luo L,Zhang G,Pan J,et al.Flow and heat transfer characteristics of falling water film on horizontal circular and non-circular cylinders[J].Journal of Hydrodynamics,2013,25(3):404-414.
[18]	Luo Lincong(罗林聪),Zhang Guanmin(张冠敏),Tian Maocheng(田茂诚),et al.Numerical simulation of liquid film flow on horizontal circular and shaped cylinders for falling film evaporation[J].Journal of Chinese Society of Power Engineering(动力工程学报),2013,34(4):710-714.
[19]	Luo L,Zhang G,Pan J,et al.Influence of oval-shaped tube on falling film flow characteristics on horizontal tube bundle[J].Desalination and Water Treatment,2015,54(11):2939.
[20]	Pise A T,Korde N U,Salunkhe R H.Numerical simulation of falling droplets/jets over horizontal tubes[J].Inter-national Journal of Fluid Mechanics Research,2013,40(3):266.
[21]	Chen J,Zhang R,Niu R.Numerical simulation of horizontal tube bundle falling film flow pattern transformation[J].Renewable Energy,2015, 73:62-68.
[22]	Inaoka H,Ito N.Numerical simulation of pool boiling of a Lennard-Jones liquid[J].Physica A:Statistical Mechanics and Its Applications,2013,392(18):3863-3868.
[23]	Gong S,Cheng P.Numerical simulation of pool boiling heat transfer on smooth surfaces with mixed wettability by lattice Boltzmann method[J].International Journal of Heat and Mass Transfer,2015,80:206-216.
[24]	Lal S,Sato Y,Niceno B.Direct numerical simulation of bubble dynamics in subcooled and near-saturated convective nucleate boiling[J].International Journal of Heat and Fluid Flow,2015,51:16.
[25]	Sun T,Li W,Yang S.Numerical simulation of bubble growth and departure during flow boiling period by lattice Boltzmann method[J].International Journal of Heat and Fluid Flow,2013,44:120-129.
[26]	Chen Z,Utaka Y.On heat transfer and evaporation charac-teristics in the growth process of a bubble with microlayer structure during nucleate boiling[J].International Journal of Heat and Mass Transfer,2015,81:750-759.
[27]	Tsui Y Y,Lin S W,Lai Y N,et al.Phase change calcula-tions for film boiling flows[J].International Journal of Heat and Mass Transfer,2014,70:745-757.
[28]	Kuang Y W,Wang W,Zhuan R,et al.Simulation of boiling flow in evaporator of separate type heat pipe with low heat flux[J].Annals of Nuclear Energy,2015,75:158-167.
[29]	Lee W,Son G,Yoon H Y.Direct numerical simulation of flow boiling in a finned microchannel[J].International Communications in Heat and Mass Transfer,2012,39(9):1460-1466.
[30]	Zhuan R,Wang W.Flow pattern of boiling in micro-channel by numerical simulation[J].International Journal of Heat and Mass Transfer,2012,55(5):1741-1753.
[31]	Wu H L,Peng X F,Ye P,et al.Simulation of refrigerant flow boiling in serpentine tubes[J].International Journal of Heat and Mass Transfer,2007,50(5):1186-1195.
[32]	Xie L,Xie Y,Yu J.Phase distributions of boiling flow in helical coils in high gravity[J].International Journal of Heat and Mass Transfer,2015,80:7-15.
[33]	Zhuan R,Wang W.Simulation on nucleate boiling in micro-channel[J].International Journal of Heat and Mass Transfer,2010,53(1):502-512.