Conjugate heat transfer investigation of cooled turbine using the preconditioned density-based algorithm 被引量：2

导出

摘要 The preconditioned density-based conjugate heat transfer(CHT)algorithm was used to investigate the heat transfer characteristics of a cooled turbine vane.Fluid domain provided boundary heat flux for solid domain and obtained boundary temperature from it for the coupling strategy.The governing equations were solved by the preconditioned density-based finite-volume method,with preconditioning matrix,improved Abu-Gharmam Shaw(AGS)transition model,matrix dissipation scheme and four kinds of turbulence models.The grid system is multi-block structured grids for fluid domain and unstructured grids for solid domain,with full-matched grids at the fluid-solid interfaces.The effects of turbulence model,outlet Mach number,outlet Reynolds number,inlet turbulence intensity and the temperature ratio of blade surface/gas on the local heat transfer performance were studied.Results indicate that the k-o shear-stress transport(SST)and AGS model can predict the conjugate heat transfer better than others.The Mach number and Reynolds number have relatively obvious influences on the heat transfer,while the turbulence intensity and temperature ratio only have slight influences.Comparisons with experimental data demonstrate the applicability and accuracy of the numerical algorithm.

作者 Peng Wang Yu Li Zhengping Zou Weihao Zhang

机构地区 National Key Laboratory of Science and Technology on Aero-Engine Aero-Thermodynamics Beijing Institute of Nearspace Vehicle's Systems Engineering

出处《Propulsion and Power Research》 SCIE 2013年第1期56-69,共14页 推进与动力（英文）

基金 The work is financially supported by National Nature Science Foundation of China under Grant number 91130013.

关键词 Conjugate heat transfer Cooled turbine Numerical simulation PRECONDITIONING Density-based

分类号 O35 [理学—流体力学]

引文网络
相关文献

参考文献3

1林立,任静,蒋洪德.γ-Reθ转捩模型在内部冷却叶片中的应用[J].工程热物理学报,2009,30(11):1849-1852. 被引量：2
2王振峰,颜培刚,唐洪飞,黄洪雁,韩万金.高压气冷涡轮内冷通道换热系数准则式的研究[J].工程热物理学报,2010,31(2):247-250. 被引量：6
3周驰,王强,郭兆元,黄家骅,冯国泰.气冷涡轮气热耦合数值模拟[J].推进技术,2009,30(5):566-570. 被引量：7

二级参考文献29

1Bruno Facchini, Andrea Magi, Alberto Scotti Del Greco. Conjugate Heat Transfer Simulation of a Radially Cooled Gas Turbine Vane. ASME GT2004-54213, 2004. 被引量：1
2R E Mayle. The Role of Laminar-Turbulent Transition in Gas Turbine Engines, The 1991 IGTI Scholar Lecture. 被引量：1
3F R Menter. Transition Modeling for General Purpose CFD Codes. Flow Turbulence Combust, 2006, 77: 277- 303. 被引量：1
4Hylton L D, Mihelc M S, Turner E R, et al. Analytical and Experimental Evaluation of the Heat Transfer Distri- bution over the Surface of Turbine Vanes. NASA Paper No. CR-168015, 1983. 被引量：1
5Mayle R E. The Path to Predicting Bypass Transition. Journal of Turbomachinery, 1997, 119:405-411. 被引量：1
6Dieter Bohn. Combined Aerodynamic and Thermal Analysis of a High-pressure Turbine Nozzle Guide Vane. In: Proceedings of the 1995 Yokohama International Gas Turbine Congress, 1995. 被引量：1
7Jiang Luo, Eli H Razingsky. Conjugate Heat Transfer Analysis of a Cooled Turbine Vane Using the V2F Turbulence Model. Journal of Turbomachinery, 2007, 129: 773-781. 被引量：1
8Menter F R. TwoFEquation Eddy Viscosity Turbulence Models for Engineering Applications, AIAA Journal, 1994, 32(8): 1598 -1605. 被引量：1
9Menter F R, Langtry R B. A Correlation-Based Transition Model Using Local Variables Part Ⅰ-Model Formulation. ASME GT2004-53452, 2004. 被引量：1
10David C Wilcox. Simulation of Transition with a Two- equation Turbulence Model. AIAA Journal, 1994, 32(2): 247-255. 被引量：1

共引文献11

1张强,刘巨保,赵晓荣.换热管流固耦合传热的分区求解数值算法[J].科学技术与工程,2010,10(28):6907-6911. 被引量：6
2温惠,谭震宇,唐宗华,孙树敏,李庆民.金属氧化物限压器冷却结构设计及其三维温度场仿真分析[J].高电压技术,2011,37(9):2328-2336. 被引量：7
3孙润鹏,朱卫兵,徐凌志,郭昊雁,陈宏.应用Transition k-kl-ω转捩模型对内冷叶片气热耦合的数值模拟[J].推进技术,2012,33(2):274-282. 被引量：7
4Zhang Hongjun,Zou Zhengping,Li Yu,Ye Jian,Song Songhe.Conjugate heat transfer investigations of turbine vane based on transition models[J].Chinese Journal of Aeronautics,2013,26(4):890-897. 被引量：6
5薛立民,范正赟,朱长军,彭军山,董凤杰,郭海涛.260t/h大型干熄焦炉环形烟道内墙应力场[J].钢铁,2019,54(1):99-104. 被引量：1
6陈朔,罗磊,王松涛.燃气涡轮无气膜动叶的内流流场和气热耦合计算[J].汽轮机技术,2014,56(5):329-331.
7李涛,边昕,马海红,黄洪雁.湍流、转捩模型对气冷涡轮气热耦合计算影响的对比研究[J].热能动力工程,2014,29(6):610-616. 被引量：1
8杨梦,张美杰,邵志君,朱应军,顾华志.干熄焦炉环形风道内墙损毁的应力分析与修复[J].煤炭转化,2017,40(5):50-55. 被引量：4
9王则力,巨亚堂,张凯,武小峰.涡轮叶片辐射热冲击疲劳试验应力温度场模拟仿真[J].航天器环境工程,2019,36(4):307-312. 被引量：7
10曾军,张维涛,王鹏飞,雷鸣,郑振江.空心气冷低压涡轮动叶气热耦合数值模拟[J].推进技术,2020,41(6):1268-1275. 被引量：3

同被引文献8

1M.SHEIKHOLESLAMI,D.D.GANJI,H.R.ASHORYNEJAD,H.B.ROKNI.Analytical investigation of Jeffery-Hamel flow with high magnetic field and nanoparticle by Adomian decomposition method[J].Applied Mathematics and Mechanics(English Edition),2012,33(1):25-36. 被引量：11
2M.SHEIKHOLESLAMI,M.GORJI-BANDPY,G.DOMAIRRY.Free convection of nanofluid filled enclosure using lattice Boltzmann method (LBM)[J].Applied Mathematics and Mechanics(English Edition),2013,34(7):833-846. 被引量：9
3Zhang Hongjun,Zou Zhengping,Li Yu,Ye Jian,Song Songhe.Conjugate heat transfer investigations of turbine vane based on transition models[J].Chinese Journal of Aeronautics,2013,26(4):890-897. 被引量：6
4Jinguang Yang,Hu Wu.The development and application of an inviscid inverse method[J].Propulsion and Power Research,2013,2(2):131-138. 被引量：1
5Majid Rezazadeh Reyhani,Mohammad Alizadeh,Alireza Fathi,Hiwa Khaledid.Turbine blade temperature calculation and life estimation-a sensitivity analysis[J].Propulsion and Power Research,2013,2(2):148-161. 被引量：9
6Sudip Bhattrai,Hao Tangn.Comparative performance analysis of combinedcycle pulse detonation turbofan engines (PDTEs)[J].Propulsion and Power Research,2013,2(3):214-224. 被引量：7
7AMIRI DELOUEI Amin,EMAMIAN Amin,SAJJADI Hasan,ATASHAFROOZ Meysam,LI Yueming,WANG Lian-Ping,JING Dengwei,XIE Gongnan.A Comprehensive Review on Multi-Dimensional Heat Conduction of Multi-Layer and Composite Structures:Analytical Solutions[J].Journal of Thermal Science,2021,30(6):1875-1907. 被引量：1
8王海,范芳苏,浦健,王建华,刘明侯,王春华,陆海鹰.带凹坑圆孔气膜冷却流动传热特性[J].航空动力学报,2022,37(3):492-501. 被引量：2

引证文献2

1F.Shakeri Aski,Seyed Jalal Nasirkhani,E.Mohammadi,A.Asgari.Application of Adomian decomposition method for micropolar flow in a porous channel[J].Propulsion and Power Research,2014,3(1):15-21. 被引量：3
2ZHANG Zhixin,ZENG Wu,ZHANG Xiaodong,ZENG Yuntao.Comparative Study on Different Methods for Prediction of Thermal Insulation Performance of Thermal Barrier Coating Used on Turbine Blades[J].Journal of Thermal Science,2024,33(1):172-189.

二级引证文献3

1张雪,孙峪怀.广义的(3+1)维Kadomtsev-Petviashvili方程的动力分析及其行波解[J].数学物理学报（A辑）,2019,39(3):501-509. 被引量：3
2F.Shakeri Aski,Seyed Jalal Nasirkhani,E.Mohammadian,A.Asgari.Errata for the article“Application of Adomian decomposition method for micropolar flow in a porous channel”[J].Propulsion and Power Research,2021,10(3):314-315.
3S.Sepasgozar,M.Faraji,P.Valipour.Application of differential transformation method (DTM) for heat and mass transfer in a porous channel[J].Propulsion and Power Research,2017,6(1):41-48. 被引量：3

1Dailin YAO,San Shing CHOI,King Jet TSENG,Tek Tjing LIE.Frequency control ancillary service provided by a wind farm:dual-BESS scheme[J].Journal of Modern Power Systems and Clean Energy,2014,2(2):93-103. 被引量：4
2李晶.论普通法民事诉讼中的“自然法院”[J].中国国际私法与比较法年刊,2013,16(1):129-140.
3YANG Duo-Xing,ZHANG De-Liang.Applications of the CE/SE Scheme to Incompressible Viscous Flows in Two-Sided Lid-Driven Square Cavities[J].Chinese Physics Letters,2012,29(8):176-180.
4Yu-Jia Sun,Shu Zheng.Calculation of radiative heat flux on irregular boundaries in participating media[J].Chinese Physics B,2020,29(12):322-328.
5Song Kexin,Zhang Jie,Zhai Xiaoyue.Morphometric studies of the capillary loop stage glomerulus in developing mice[J].解剖学杂志,2021,44(S01):171-172.
6Yu Wu,Jing Tao,Jiehao Wang,Yan Zhang,Shuhua Peng.Experimental investigation of shale breakdown pressure under liquid nitrogen pre-conditioning before nitrogen fracturing[J].International Journal of Mining Science and Technology,2021,31(4):611-620. 被引量：3
7YE Lin,LIU Cunliang,XU Zhipeng,ZHU Huiren,LIU Haiyong,ZHAI Yingni.Experimental Investigation on the Adiabatic Film Effectiveness for Counter-Inclined Simple and Laid-Back Film-Holes of Leading Edge[J].Journal of Thermal Science,2020,29(3):772-783. 被引量：3
8XU You-Sheng,WU Bin,ZHENG You-Qu,FAN Jin-Tu.Simultaneous Recovery of Porosity (Porosity Seed) and Total Heat Transmissionin Fibrous Porous Materials[J].Chinese Physics Letters,2013,30(6):127-130.
9Ping-Chen Wu,Jiahn-Horng Chen.Numerical study on cavitating flow due to a hydrofoil near a free surface[J].Journal of Ocean Engineering and Science,2016,1(3):238-245.
10Qing Xu,Xiaohua(Michael)Xuan.Nonlinear regression without i.i.d.assumption[J].Probability, Uncertainty and Quantitative Risk,2019,4(1):118-132.

Propulsion and Power Research

2013年第1期

浏览历史

内容加载中请稍等...