英文期刊论文

2020

[35]Ji W-T, Lu X-D, Yu Q-N, et al. Film-wise condensation of R-134a, R-1234ze(E) and R-1233zd(E) outside the finned tubes with different fin thickness[J]. International Journal of Heat and Mass Transfer, 2020, 146: 118829.

[34]Ji W-T, Mao S-F, Chong G-H, et al. Effect of Fin Structure on the Condensation of R-134a, R-1234ze(E), and R-1233zd(E) Outside theTitanium Tubes[J]. Journal of heat transfer, 2020, 142 (1):014502.

 

2019

[33]Mao S-F, Ji W-T*, Chong G-H, et al. Numerical investigation on the nucleate pool boiling heat transfer of R134a outside the plain tube[J]. Numerical Heat Transfer, Part A: Applications, 2019, 76 (11): 889-908.

[32]Ji W-T, Mao S-F, Chong G-H, et al. Numerical and experimental investigation on the condensing heat transfer of R134a outside plain and integral-fin tubes[J]. Applied Thermal Engineering, 2019, 159: 113878.

[31]Ji W-T, Fan J-F, Zhao C-Y, Tao WQ. A revised performance evaluation method for energy saving effectiveness of heat transfer enhancement techniques[J]. International Journal of Heat and Mass Transfer, 2019, 138: 1142-1153.

[30]Jin P-H, Zhang Z, Mostafa I, Zhao C-Y, Ji WT, Tao WQ.. Heat transfer correlations of refrigerant falling film evaporation on a single horizontal smooth tube[J]. International Journal of Heat and Mass Transfer, 2019, 133: 96-106.

[29]Li S-Y, Ji W-T*, Zhao C-Y, et al. Effects of magnetic field on the pool boiling heat transfer of water-based α-Fe2O3 and γ-Fe2O3 nanofluids[J]. International Journal of Heat and Mass Transfer, 2019, 128: 762-772.

[28]Ji W-T, Zhao E-T, Zhao C-Y, et al. Falling film evaporation and nucleate pool boiling heat transfer of R134a on the same enhanced tube[J]. Applied Thermal Engineering, 2019, 147: 113-121.

 

2018

[27]Ji W-T*, Chong G-H, Zhao C-Y, et al. Condensation heat transfer of R134a, R1234ze(E) and R290 on horizontal plain and enhanced titanium tubes[J]. International Journal of Refrigeration, 2018, 93: 259-268.

[26]Jin P-H, Zhao C-Y, Ji W-T, et al. Experimental investigation of R410A and R32 falling film evaporation on horizontal enhanced tubes[J]. Applied Thermal Engineering, 2018, 137: 739-748.

[25]Zhao C-Y, Ji W-T, Jin P-H, et al. Cross vapor stream effect on falling film evaporation in horizontal tube bundle using R134a[J]. Heat Transfer Engineering, 2018, 39 (7-8): 724-737.

[24]Zhang H, Zhang C, Ji W,T et al. Experimental Characterization of the Thermal Conductivity and Microstructure of Opacifier-Fiber-Aerogel Composite[J]. Molecules, 2018, 23 (9): 2198.

[23]Zhao C-Y, Ji W-T, Jin P-H, et al. Effect of downward vapor stream on falling film evaporation of R134a in a tube bundle[J]. International Journal of Refrigeration, 2018, 89: 112-121.

[22]JI W-T*, Zhao C-Y, Lofton J, et al. Condensation of R134a and R22 in shell and tube condensers mounted with high density low-fin tubes[J]. Journal of heat transfer, 2018, 140 (9): 091503.

[21]Ji WT*, Zhao P-F, Zhao C-Y, et al. Pool boiling heat transfer of water and nanofluid outside the surface with higher roughness and different wettability[J]. Nanoscale and Microscale Thermophysical Engineering, 2018: 1-28.

[20]Zhao C-Y, Ji W-T, He Y-L, et al. A comprehensive numerical study on the subcooled falling film heat transfer on a horizontal smooth tube[J]. International Journal of Heat and Mass Transfer, 2018, 119: 259-270.

[19]Zhao C-Y, Ji W-T, Jin P-H, et al. Hydrodynamic behaviors of the falling film flow on a horizontal tube and construction of new film thickness correlation[J]. International Journal of Heat and Mass Transfer, 2018, 119: 564-576.

[18]Zhao C-Y, Ji W-T, Jin P-H, et al. Experimental study of the local and average falling film evaporation coefficients in a horizontal enhanced tube bundle using R134a[J]. Applied Thermal Engineering, 2018, 129: 502-511.

 

2017

[17]Ji W-T*, Zhao C-Y, Zhang D-C, et al. Pool boiling heat transfer of R134a outside reentrant cavity tubes at higher heat flux[J]. Applied Thermal Engineering, 2017, 127: 1364-1371.

[16]Zhao C-Y, Ji W-T, Jin P-H, Zhong YJ, Tao WQ*. The influence of surface structure and thermal conductivity of the tube on the condensation heat transfer of R134a and R404A over single horizontal enhanced tubes[J]. Applied Thermal Engineering, 2017, 125.

[15]Mou S-C, Luan Y-X, Ji W-T*, Zhang JF, Tao WQ. An example for the effect of round-off errors on numerical heat transfer[J]. Numerical Heat Transfer, Part B: Fundamentals, 2017, 72 (1): 21-32.

[14]Ji W-T*, Jacobi AM, He Y-L, Tao WQ. Summary and evaluation on the heat transfer enhancement techniques of gas laminar and turbulent pipe flow[J]. International Journal of Heat and Mass Transfer, 2017, 111: 467-483.

[13]Zhao C-Y, Jin P-H, Ji W-T, Tao WQ*. Experimental investigations of R134a and R123 falling film evaporation on enhanced horizontal tubes[J]. International Journal of Refrigeration, 2017, 75: 190-203.

 

2016

[12] W.-T. Ji, C.-Y. Zhao, D.-C. Zhang, S. Yoshioka, Y.-L. He, W.-Q. Tao*, Effect of vapor flow on the falling film evaporation of R134a outside a horizontal tube bundle, International Journal of Heat and Mass Transfer, 92 (2016) 1171-1181.

[11] C.-Y. Zhao, W.-T. Ji, P.-H. Jin, W.-Q. Tao*, Heat transfer correlation of the falling film evaporation on a single horizontal smooth tube, Applied Thermal Engineering, 103 (2016) 177-186.

 

2015

[10]Ji WT, Numata M, He Y-L, Tao Wen-Quan*. Nucleate pool boiling and filmwise condensation heat transfer of R134a on the same horizontal tubes[J]. International Journal of Heat and Mass Transfer, 2015, 86: 744-754.

[9]Ji W-T, Li Z-Y, Qu Z-G, Tao W-Q*. Film condensing heat transfer of R134a on single horizontal tube coated with open cell copper foam[J]. Applied Thermal  Engineering, 2015, 76: 335-343.

[8]Ji W-T, Jacobi AM, He Y-L, Tao W-Q*. Summary and evaluation on single-phase heat transfer enhancement techniques of liquid laminar and turbulent pipe flow[J]. International Journal of Heat and Mass Transfer, 2015, 88: 735-754.

[7]Ji W-T, Zhao C-Y, He Y-L, Tao WQ*. Experimental validation of Cooper correlation at higher heat flux[J]. International Journal of Heat and Mass Transfer, 2015, 90: 1241-1243.

 

2014
[6] Ji W-T, Zhao C-Y, Zhang D-C, Tao W-Q*. Condensation of R134a outside single horizontal titanium, cupronickel (B10 and B30), stainless steel and copper tubes[J]. International Journal of Heat and Mass Transfer, 2014, 77: 194-201.


2012

[5].Ji WT, Zhao CY, Zhang DC, He YL,Tao WQ*. Influence of condensate inundation on heat transfer of R134a condensing on three dimensional enhanced tubes and integral-fin tubes with high fin density[J]. Applied Thermal Engineering, 2012, 38 (0): 151-159.(SCI:917UV) 

 

2011
[4].Ji WT,Qu ZG*, Li ZY, Guo JF, Zhang DC, Tao WQ, Pool boiling heat transfer of R134a on single horizontal tube surfaces sintered with open-celled copper foam[J], International Journal of Thermal Science,2011,50(1): 2248-2255.(SCI:820XE)
[3].Ji WT, Zhang DC, He, YL, Tao WQ*, Prediction of Fully Developed turbulent Heat Transfer of Internal Helically Ribbed Tubes - an Extension of Gnielinski Equation, International Journal of Heat and Mass Transfer, 2011, 55 (4): 1375-1384.(SCI:895BC)

 

2010

[2].Ji WT, Zhang DC, Feng N, Guo J. F. Numata, M. Xi G. N. Tao W Q*. Nucleate Pool Boiling Heat Transfer of R134a and R134a PVE Lubricant Mixtures on Smooth and Five Enhanced Tubes[J]. Journal of Heat Transfer- ASME, 2010, 132 (11): 8.(SCI:672VM)

 

2007

[1].Zhang DC, Ji WT, Tao WQ*. Condensation heat transfer of HFC134a on horizontal low thermal conductivity tubes[J]. International Communications in Heat and Mass Transfer, 2007, 34 (8): 917-923.(SCI:212CD)
 

国际会议论文

2019

[11]Ji WT, Chong GH, Mao SF, Zhao CY, Tao WQ,Condensation heat transfer of R134a and R1234ze(E) on horizontal tubes coated with hydrophobic films,5th International Workshop on Heat-Mass Transfer Advances for ENERGY CONSERVATION and POLLUTION CONTROL,13-16 August 2019, Novosibirsk, Russia

[10]Mao SF, Ji* WT, Yu QN, Lu XD, Tao WQ,3D numerical simulation of plate heat exchangers with three different surface structures,The 7th Asian Symposium on Computational Heat Transfer and Fluid Flow- 2019,Sep. 3-7, 2019, Tokyo,  Japan

 

2018

[9]JI W-T*, Zhao C-Y,  et al.Comparative study on the pool boiling and falling film evaporation of refrigerant r134a outside the same tubes,16th International Heat Transfer Conference, IHTC-16, August 10-15, 2018, Beijing, China

 

2017

[8] Wen-Tao JI*, Chuang-Yao ZHAO, Ding-Cai ZHANG, Zeng-Yao LI, Ya-Ling HE, Wen-Quan TAO, Pool boiling heat transfer of R134a outside reentrant cavity tubes at higher heat flux,2017 American Society of Thermal and Fluids Engineers (ASTFE) Conference and 4th International Workshop on Heat Transfer (IWHT), April 2-5, 2017,Las Vegas, NV, USA.

 

2015

[7].C.Y. Zhao, W.T. Ji, P. H. Jin, W.Q. Tao,Cross vapor flow effect on falling film evaporation outside horizontal tube bundle using R134a,The 3rd International Workshop on Heat Transfer Advances for Energy Conservation and Pollution Control (IWHT2015) October 16-19, 2015, Taipei, Taiwan

 

2014

[6]Ji W-T, Zhao C-Y, Dai Q-B, Tao WQ. Experimental Study of Water Cooled Condenser Made of Three Dimensional and High Fin Density Integral-Finned Tubes[C]: ASME 2014 International Mechanical Engineering Congress & Exposition, November 14-20,2014, Montreal,Canada.
[5] Ji W-T, Zhao C-Y, He Y-L, Tao W-Q Vapor flow effect on falling film evaporation outside horizontal tube bundle. The 15th International Heat Transfer Conference(IHTC-15)-8581, August 10-15th 2014. Kyoto, Japan.
[4] Ding-cai Zhang, Wen-tao Ji, Jia-di Du, Zhen Zhang, Xiao-wei Fan, Ya-Ling He, Wen-Quan Tao. Parameter Comparison of Condensation Heat Transfer of R134a Outside Horizontal Low-Finned Tubes. The 15th International Heat Transfer Conference(IHTC-15)-8581, August 10-15th 2014. Kyoto, Japan.

 

2013

[3]Chen L, Ji WT, Tao WQ. Coupling Finite Volume method and Lattice Boltzmann Method for Multi-Scale Multiple Physicochemical processes, The 4th Asian Symposium on Computational Heat Transfer and Fluid Flow, 2013, HongKong, China
[2]Zhao CY, Ji WT, Tao WQ Numerical Study on Flow Characteristics of Falling Film on a Horizontal Circular Tube, The 4th Asian Symposium on Computational Heat Transfer and Fluid Flow, 2013, HongKong, China

 

2012

[1].Chuangyao Zhao, Wentao Ji, Yaling He, Wenquan Tao,Falling Film Evaporation—A Review and Test Rig Construction, 4th International Symposium on Heat Transfer and Energy Conservation. January 6-9, 2012 Guangzhou, China

中文期刊论文

[10]冀文涛, 张定才, 赵创要,  何雅玲, 陶文铨. 高热通量水平管外池沸腾传热[J]. 化工学报, 2016, 67 (S1): 28-32.

[9] 郭剑飞, 李增耀, 屈治国, 冀文涛, 陶文铨, 水平金属泡沫管外R134a凝结传热实验研究, 工程热物理学报, 32(5) (2011) 839-842.

[8] 冀文涛, 屈治国, 郭剑飞, 张定才, 陶文铨, 水平管外开孔铜泡沫R134a池沸腾换热实验研究, 工程热物理学报, 31(7) (2010) 1185-1188.

[7]冀文涛, 冯楠, 张定才, 郭剑飞, 陶文铨, 润滑油对水平管外R134a池沸腾换热的影响, 工程热物理学报, 30(5) (2009) 821-823.

[6]张定才, 冀文涛, 陶文铨, 何雅玲, 不凝气体对R123凝结换热的影响, 工程热物理学报, 30(12) (2009) 2062-2064.

[5]冀文涛, 张定才, 冯楠, 陶文铨, 水平管外含油及纯R134a池沸腾换热特性比较, 工程热物理学报, 29(7) (2008) 1195-1198.

[4]赵创要,冀文涛,陶文铨. R404A在低导热系数管外凝结传热的实验研究.工程热热物理学报,35(1)132-135.
[3] 赵创要,冀文涛,陶文铨.R134a在水平管外降膜蒸发的实验研究 .工程热热物理学报.179-183.
[2] 张定才,杜佳迪, 冀文涛,张振,朱春洁, 何雅玲, 陶文铨.R134a/R125混合工质水平管外凝结换热.化工学报.65(S1)119-124
[1] 张定才,田松娜,冀文涛,赵安利,范晓伟; 陶文铨.R417A在水平双侧强化管外沸腾换热研究 .制冷学报,35(3)114-118.

国内会议论文

[13].崇国魂,毛帅峰,冀文涛*,陶文铨.R134a、R1234ze(E)在水平钛管外凝结换热的实验研究[C]. 中国工程热物理年会传热传质学学术会议论文. 哈尔滨,2018(10).

[12].赵鹏飞,冀文涛*,何雅玲,陶文铨.疏水/超疏水表面池沸腾换热特性研究[C]. 中国工程热物理年会传热传质学学术会议论文. 苏州,2017(10).

[11]赵二涛,冀文涛*,李增耀等.R134a在水平双侧强化管外池沸腾换热特性的研究[C].中国工程热物理年会传热传质学学术会议论文,北京,2016(10).

[10]冀文涛*, 张定才,赵创要,何雅玲,陶文铨,高热流密度强化管外R134a池沸腾传热的实验研究. 中国工程热物理年会传热传质学学术会议论文,大连,2015(10).

[9]赵创要,冀文涛,靳蒲航,何雅玲,陶文铨,饱和温度及热流密度对水平单管外降膜蒸发的影响[C].中国工程热物理年会传热传质学学术会议论文,西安,2014(10).

[8]赵创要,冀文涛,陶文铨,水平管外R134a降膜蒸发实验研究[C].中国工程热物理年会传热传质学学术会议论文,重庆,2013(10).

[7]赵创要,冀文涛,陶文铨,低导热系数管外R404A凝结传热实验研究[C].中国工程热物理年会传热传质学学术会议论文,东莞,2012(10).

[6]冀文涛,赵创要,张定才,陶文铨.低肋管 R134a 凝结换热的实验研究[C].中国工程热物理年会传热传质学学术会议论文, 西安,2011(10).
[5]冀文涛,冯楠, 张定才,何雅玲,陶文铨.内螺纹管强化管管内充分发展单相强制对流湍流传热预测[C].中国工程热物理年会传热传质学学术会议论文,西安,2011(10).

[4]冀文涛,屈治国,郭剑飞,冯楠,张定才,陶文铨,水平管外开孔铜泡沫R134a池沸腾换热实验研究[C],中国工程热物理年会传热传质学学术会议论文,2009(10).

[3]冯楠,冀文涛,郭剑飞,张定才,李增耀,陶文铨,水平管管外冷凝蒸发传热性能实验研究[C],中国工程热物理年会传热传质学学术会议论文,2008(10).

[2]冀文涛,冯楠,郭剑飞,张定才,陶文铨,润滑油对水平管 R134a池沸腾换热的影响[C],中国工程热物理年会传热传质学学术会议论文,2008(10).

[1]冀文涛,张定才,冯楠,陶文铨. 水平强化管外R134a替代R12以及R134a含微量润滑油池沸腾换热热的性能研究[C]. 中国工程热物理年会传热传质学学术会议论文,广州,2007.

 

专利

 [1] 一种卧式管壳式水冷冷凝器,实用新型,ZL201320567817.8

 [2] 一种废气余热回收换热器,发明专利,CN106017164B

 [3] 水平管束及单管外制冷工质降膜蒸发、池沸腾和凝结相变换热测试装置,ZL201710453004.9