武俊梅 |
1.纳米流体强化传热机理及应用
2.发动机涡轮叶片先进冷却技术
3.飞行器气动力及热防护技术
4.颗粒/流体两相流动换热数值模拟
1.国家自然科学基金项目“纳米流体稳定性、传热传质特性及CHF机理研究(11775172)”
2.国家自然科学基金“ 强迫循环条件下纳米流体强化临界热流密度机制研究”。(51276146)。
3.国家自然科学基金“气泡泵及其对ADS次临界堆瞬态及事故工况下的动态特性影响的实验与理论研究”。(11475133)
4.横向课题“离散介质颗粒流动理论模型研究”
1. J.M. Wu* and J. Zhao. A review of nanofluid heat transfer and critical heat flux enhancement—Research gap to engineering application. Progress in Nuclear Energy 66(2013):13-24. ESI论文, 归入其学术领域中最优秀的 1% 之列, 获Best paper award 2013. (ESI、SCI)
2. Y. Wang, K H Deng,J. M. Wu*, A Correlation of Nanofluid Flow Boiling Heat Transfer Based on the Experimental Results of AlN/H2O and Al2O3/H2O nanofluid Experimental. Thermal & Fluid Science 80 (2017) 376–383(SCI)
3. J.M. Wu*, H.Y. Liang, F.J. Zhu, J. Lei. CFD analysis of the impact of a novel spacer grid with longitudinal vortex generators on the sub-channel flow and heat transfer of a rod bundle. Nuclear Engineering and Design 324 (2017): 78–92(SCI)
4. J. Xu, J. Lei, J.M. Wu*, K. Zhang*. The three-dimensional characteristics of the unsteady wall-pressure in a low-Mach-number rectangular cavity flow with Rossiter model oscillation. Experiments in Fluids 58(2017):DOI 10.1007/s00348-017-2388-9 (SCI)
5. J.M. Wu*, J. Zhao J. Lei, B. Liu. Effectiveness of nanofluid on improving the performance of microchannel heat sink. Applied Thermal Engineering 101 (2016) 402–412(SCI)
6. Y. Wang, J.M. Wu*. Single Bubble Dynamic Behavior in Al2O3/H2O Nanofluid on Downward-facing Heating Surface. Nuclear Engineering and Technology, 48(2016): 915-924 (SCI)
7. Y. Wang, K.H. Deng, B. Liu, J.M. Wu*. Experimental study on AlN/H2O and Al2O3/H2O nanofluid flow boiling heat transfer and its influence factors in a vertical tube. The 24th International Conference on Nuclear Engineering, 2016.6, Charlotte, USA(SCI)
8. Y. Wang,J.M. Wu*.Numerical simulation on single bubble behavior during Al2O3/H2O nanofluids flow boiling using Moving Particle Simi-implicit method.Progress in Nuclear Energy 85(2015):130-135(SCI)
9. J.M. Wu*, J. Zhao, K. J. Tseng. Parametric study on the performance of double- layered microchannels heat sink.. Energy Conversion & Management, 80 (2014): 550-560(SCI)
10. J.M. Wu*, J. Zhao. Conjugated Numerical Study on the Performance of Microchannel Heat Sink Using Al2O3/H2O Nanofluid. Proceedings of the 22nd International Conference on Nuclear Engineering, 2014.7, Prague, Czech Republic. (SCI)
11. J.M. Wu*, J. Zhao, Y. Wang. Nanofluid Boiling Heat Transfer and Critical Heat Flux Enhancement—Mechanism to be Revealed. Proceedings of the 21st International Conference on Nuclear Engineering, 2013.8, Chengdu, China.(SCI)
12. J.M. Wu, W.Q. Tao. Effect of longitudinal vortex generator on heat transfer in rectangular channels.J.M. Wu* et al. Applied Thermal Engineering, 37(2012): 67-72(SCI)
13. J.M. Wu*, H. Zhang, C.H. Yan, Y.Wang. Experimental study on the performance of a novel fin-tube air heat exchanger with punched longitudinal vortex generator. Energy Conversion and Management, 57 (2012): 42–48, 2012.(SCI)
14. J.M. Wu*, W.Q. Tao. Impact of delta winglet vortex generators on the performance of a novel fin-tube surfaces with two rows of tubes in different diameters.. Energy Conversion & Management 52(2011):2895–2901
15. J.M. Wu*, X. Huang, H. Zhang. Numerical investigation on the heat and mass transfer in a direct evaporative cooler. Applied Thermal Engineering 29(2009): 195-201(SCI)
16. J.M. Wu*, X. Huang, H. Zhang. Theoretical analysis on heat and mass transfer in a direct evaporative cooler. Applied Thermal Engineering, 29(2009): 980-984(SCI)
17. J.M. Wu and W.Q. Tao. Numerical study on laminar convection heat transfer in a rectangular channel with longitudinal vortex generator, Part A: Verification of field synergy principle. Int. J. Heat Mass Transfer 51(2008): 1179-1191(SCI)
18. J.M. Wu and W.Q. Tao. Numerical study on laminar convection heat transfer in a rectangular channel with longitudinal vortex generator, Part B: Parametric trends. Int. J. Heat Mass Transfer 51(2008): 3683-3692(SCI)
19. J.M. Wu and W.Q. Tao. Investigation on laminar convection heat transfer in fin-and-tube heat exchanger in aligned arrangement with longitudinal vortex generator from the viewpoint of field synergy principle. Applied Thermal Engineering, 27(2007): 2609-2617(SCI)
20. J.M. Wu and W.Q. Tao. Numerical computation of laminar natural convection heat transfer around a horizontal compound tube with external longitudinal fins. Heat Transfer Engineering, 28 (2007): 93-102(SCI)
Sakanova Assel, Yin Shan, Zhao Jiyun, Wu J M, Leong K C. Optimization and comparison of double-layer and double-side micro-channel heat sinks with nanofluid for power electronics cooling. Applied Thermal Engineering, 65(1-2): 124-134, 2014(SCI)