国家发明专利

没有找到条目。
专利名称 申请号 专利类型 申请日期
一种基于超声波的末级静叶除湿结构 202210423163.5 发明 2022.04.21
一种基于超声波强化传热的透平叶片内部冲击冷却结构 202110383953.0 发明 2021.04.09
一种基于蒸汽冷却的双层透平叶片内部冷却结构 201910568960.0 发明 2019.06.27
一种紧凑型交流电弧加热装置及其驱动方法 201711308978.4 发明 2017.11.30
一种基于动态加热的流动湿蒸汽湿度传感器及测量方法 201710247300.3 发明 2016.08.01
一种基于电弧加热的流动湿蒸汽湿度传感器及测量方法 201611192830.4 发明 2015.09.01
一种测量流动湿蒸汽湿度、压力和速度的传感器及方法 201510101057.5 发明 2015.06.04
一种流动湿蒸汽湿度探针标定装置及方法 201510304706.1 发明 2015.06.04
一种利用微波硬同轴线的湿蒸汽湿度测量探针及方法 201410686897.8 发明 2014.11.24
基于微波加热的流动湿蒸汽湿度测量探针及其测量方法 201410136475.3 发明 2014.04.04
20条目 每页

显示10结果中的1-10。

学术论文

  1. Zhiwei Zhang, Xiaoming Wu, Liang Li, RuiYang, Jiandao Yang. Experimental validation of sonic speed theory for wet steam. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 2022, 236(5): 927-936.
  2. Wang Jiefeng, Li Liang, Li Jianwu, Wu Fan, Du Changhe. Numerical investigation on flow and heat transfer characteristics of vortex cooling in an actual film-cooled leading edge. Applied Thermal Engineering, 2021, 185: 115942.
  3. Li Sen, Li Liang. Computational investigation of baffle influence on windage loss in helical geared transmissions. Tribology International, 2021, 156: 106852
  4. Fan Xiaojun, He Chuangxin, Gan Lian, Li Liang, Du Changhe. Experimental study of swirling flow characteristics in a semi cylinder vortex cooling configuration. Experimental Thermal and Fluid Science, 2020: 110036
  5. Wu F, Li L, Wang J, et al. Numerical investigations on flow and heat transfer of swirl and impingement composite cooling structures of turbine blade leading edge. International Journal of Heat and Mass Transfer, 2019, 144: 118625
  6. XiaojunFan, Liang Li. Cooling methods for gas turbine blade leading edge: Comparative study on impingement cooling, vortex cooling and double vortex cooling. International Communications in Heat and Mass Transfer. 2019, 100: 133-145
  7. Wang J, Du C, Wu F, et al. Investigation of the vortex cooling flow and heat transfer behavior in variable cross-section vortex chambers for gas turbine blade leading edge. International Communications in Heat and Mass Transfer, 2019, 108: 104301
  8. Wu F, Li L, Du C, et al. Effects of circumferential nozzle number and temperature ratio on swirl cooling characteristics. Applied Thermal Engineering, 2019, 154: 332-342
  9. Fan X, Li L, Wang J, et al. Heat Transfer Enhancement for Gas Turbine Blade Leading Edge Cooling Using Curved Double-Wall/Vortex Cooling With Various Disturbing Objects//ASME Turbo Expo 2019: Turbomachinery Technical Conference and Exposition
  10. Starzmann Jörg; Hughes Fiona R; Schuster Sebastian; White Alexander J; Halama, Jan; Hric Vladimir; Kolovratník Michal; Lee Hoon; Sova Libor; Št’astný, Miroslav; Grübel Marius; Schatz Markus; Vogt Damian M; Patel Yogini; Patel Giteshkumar; Turunen-Saaresti Teemu; Gribin Vladimir; Tishchenko Victor; Gavrilov Ilya; Kim Changhyun; Baek Jehyun; Wu Xiaoming; Yang Jiandao; Dykas Sławomir ;Wróblewski Włodzimierz; Yamamoto Satoru; Feng, Zhenping; Li Liang. Results of the International Wet Steam Modelling Project, IMechE Part A: Journal of Power and Energy, 2018,232(5): 550-570
  11. Luan Yuxuan, Du Changhe, Fan Xiaojun, Wang Jiefeng, Li Liang. Investigations of flow structures and heat transfer in a swirl chamber with different inlet chambers and various aerodynamic parameters. International Journal of Heat and Mass Transfer, 2018, 118: 551-561
  12. Li Liang, Wu Xiaoming, Yang Jiandao, Feng Zhenping. Effects of location, shape and width of a suction slot on the water removal performance of a hollow stator blade. Proc. IMechE Part A: Journal of Power and Energy, 2018, 232(5): 461-472
  13. Li Liang, Du Changhe, Chen Xiuxiu, Wang Jiefeng, Fan Xiaojun. Numerical study on flow and heat transfer behavior of vortex and film composite cooling. Journal of Mechanical Science and Technology, 2018, 32(6): 2905-2917
  14. Fan Xiaojun, Li Liang, Zou Jiashen, Wang Jiefeng, Wu Fan. Local heat transfer of vortex cooling with multiple tangential nozzles in a gas turbine blade leading edge cooling passage. International Journal of Heat and Mass Transfer, 2018, 126: 377-389
  15. Du Changhe, Li Liang, Fan Xiaojun. Numerical study on vortex cooling flow and heat transfer behavior under rotating conditions. International Journal of Heat and Mass Transfer, 2017, 105: 638-647
  16. Du Changhe, Li Liang, Fan Xiaojun, Feng Zhenping. Rotational influences on aerodynamic and heat transfer behavior of gas turbine blade vortex cooling with bleed holes. Applied Thermal Engineering, 2017, 121: 302-313
  17. Fan Xiaojun, Du Changhe, Li Liang, Li Sen. Numerical simulation on effects of film hole geometry and mass flow on vortex cooling behavior for gas turbine blade leading edge. Applied Thermal Engineering, 2017, 112: 472-483
  18. Wu Xiaoming, Yang Jiandao, Li Liang. Study on water extraction of hollow stationary blade under wet steam flow conditions. 12th European Conference on Turbomachinery Fluid Dynamics and Thermodynamics, 2017
  19. Du Changhe, Li Liang, Wu Xin, FengZhenping. Effect of jet nozzle geometry on flow and heat transfer performance of vortex cooling for gas turbine blade leading edge. Applied Thermal Engineering, 2016, 93:1020-1032
  20. Du Changhe, Li Liang, Li Sen, FengZhenping. Effects of aerodynamic parameters on steam vortex cooling behavior for gas turbine blade leading edge. Proc. IMechE Part A: Journal of Power and Energy, 2016, 230(4): 354-365
  21. Liang Li, Changhe Du, Xiaojun Fan and Gangyun Zhong. Optimisation of a low-pressure multistage steam turbine towards decreasing the wetness losses and aerodynamic losses. Proc IMechE part A: Journal of Power and Energy, 2016, 230(4):345-353
  22. Du Changhe, Li Liang, Chen Xiuxiu, Fan Xiaojun, FengZhenping. Numerical Study on effects of jet nozzle angle and number on vortex cooling behavior for gas turbine blade leading edge, ASME Paper GT2016-57390, ASME Turbo Expo 2016: Turbomachinery Technical Conference and Exposition, 2016, Vol 58, PP. V05BT11A014; 8 pages Seoul, South Korea, June 13–17, 2016
  23. Wu Zhihua, Li Liang, Feng Zhenping. Study of steady and unsteady wet steam condensing flows in a turbine stage. Academic Journal of Xi'an Jiaotong University, 2007, 19(2): 154-158.
  24. Wu Xiaoming, Li Liang, Li Guojun, Feng Zhenping. Numerical Investigation of the Effect of Inlet Condition on Self-excited Oscillation of Wet Steam Flow in a Supersonic Turbine Cascade. International Journal for Numerical Methods in Fluids. 2009, 60(12): 1334-1350
  25. Li L, Li Y, Wu L W, You W, Li J, Feng Z P. Numerical Study on Condensing Flow in Low Pressure Cylinder of a 300MW Steam Turbine. ASME paper GT2010-23021
  26. Yu Li, Liang Li, Tong Zhao, Jun Li. Aerodynamic optimisation of a low-pressure multistage turbine using the response-surface method. Journal of Mechanical Science and Technology, 2013, 27(8): 2537-2546
  27. Sun Xiuling, Li Liang1 and Li Guojun. Transonic flow of moist air around the ONERA M6 wing with non-equilibrium and homogeneous condensation. Research Journal of Applied Sciences, Engineering and Technology. 2013, 6(10): 1825-1833.
  28. Sun Xiuling, Li Liang and Li Guojun. Transonic moist air flows with release of latent heat by non-equilibrium condensation. Proc IMechE, Part G: Journal of Aerospace Engineering, 2014, 228(7): 1083-1094
  29. Li Liang, Li Yu , Xie Xiaolong, Li Jun. Quantitative Evaluation of Wetness Losses in Steam Turbines Based on Three-dimensional Simulations of Non-equilibrium Condensing Flows. IMechE, Part A: Journal of Power and Energy, 2014, 228(6): 708-716
  30. LI Liang, SUN Xiuling, FENG Zhenping and LI Guojun. Transonic Flow of Moist Air Around a NACA 0012 Airfoil with Non-equilibrium Condensation. Progress in Natural Science, 2005, 15(9): 838-842
  31. Liang LI, Guojun LI, Zhenping FENG. Numerical Study of Flow with Spontaneous Condensation in the Low Pressure Stages of a Steam Turbine. 5th International Symposium on Multiphase Flow, Heat Mass Transfer and Energy Conversion, Xi’an, China, 3-6 July 2005.
  32. Wu ZhiHua, Guo Ge, Li Liang, Feng ZhenPing. Wet Steam Flow with Ion-induced Condensation in a One-dimensional Nozzle. 5th International Symposium on Multiphase Flow, Heat Mass Transfer and Energy Conversion, Xi’an, China, 3-6 July 2005.
  33. Liang Li, Zhenping Feng, Guojun Li. Study on Effects of Spontaneous Condensation on Performance of Low Pressure Stages in a Steam Turbine. ASME Turbo Expo 2006: Power for Land, Sea and Air. May 8-11, 2006, Barcelona, Spain
  34. LI Liang, SUN Xiuling, LI Guojun, FENG Zhenping. Numerical investigation on the self-excited oscillation of wet steam flow in a supersonic turbine cascade. Progress in Natural Science, 2006, 16(9): 988-992.
  35. Zhenping FENG, Liang LI, Guojun LI, Yoshio SHIKANO, Numerical simulation of three- dimensional transonic two-phase flows with spontaneous condensation. Proceeding of International Conference on Power Engineering. Xi’an, China, Oct. 8-12, 2001: 812-819
  36. Li Guojun, Feng Zhengping, Li Liang. Numerical simulation of three-dimensional viscous flows in a transonic turbine cascade using compressible turbulence model. CFD Journal, 2002, 10(4): 520-524.
  37. Liang LI, Guojun LI, Zhengping FENG, Numerical simulation of spontaneously condensing flows in a plane turbine cascade. TASK QUARTERLY , 2002, 6(1): 209-216
  38. Li L, Feng Z P, Li G J, Numerical simulation of wet steam condensing flow with a Eulerian/Eulerian model. Chinese Journal of Mechanical Engineering, 2003, 16(2): 156-159.
  39. Guojun Li, Zhenping Feng, Moujin Zhang, Liang Li. A turbulence model considering compressibility in three-dimensional transonic turbulent flow calculation. Journal of Thermal Science, 20009(2): 97-102
  40. 张志伟,李亮. 吸雨对压气机叶栅气动性能影响的实验研究,推进技术,202243(3): 200615.
  41. 朱华,严彪,刘雨松,李荣,李亮. 吹风比和湿空气含湿量对平板气膜冷却流动与传热特性的影响. 西安交通大学学报,2022, 56(6): 151-163.
  42. 朱华,严彪,刘雨松,李亮. 湿空气透平冷却技术研究. 发电技术,2021,42(4): 412-421.
  43. 符阳春,李健武,廖贵鄂,张志伟,李亮.湿燃气透平叶片热流耦合换热特性的数值研究.动力工程学报,2021,41(10): 849-858.
  44. 周源远,范小军,李亮,李健武,符阳春. 燃气轮机叶片前缘旋流冷却的热流固耦合数值研究. 西安交通大学学报,202054(1)135-142
  45. 李健武,符阳春,张志伟,廖贵鄂,李亮.湿空气雷诺数和含湿量对冲击冷却流动和传热特性的影响.西安交通大学学报,2020,54(5):170-178
  46. 范小军,邹佳生,周源远,李亮.喷嘴数目和温比对旋流冷却流动和传热特性影响的研究. 西安交通大学学报, 2018(3): 19-24
  47. 王杰枫, 栾宇轩, 杜长河, 范小军, 李亮. 一种新型组合内部冷却的流动和换热特性研究. 西安交通大学学报, 2018, 52(5): 108-115
  48. 王杰枫,杜长河,吴凡,范小军,李亮. 喷嘴周向位置和旋流腔拔模斜度对旋流冷却的影响. 西安交通大学学报, 2018, 52(11): 65-72
  49. 邹佳生,吴晓明,李亮,杨建道. 空心静叶蒸汽加热除湿传热特性的研究. 西安交通大学学报, 2018(5): 44-49
  50. 吴凡,杜长河,王杰枫,范小军,李亮. 周向喷嘴数对旋流冷却流动传热特性的影响. 西安交通大学学报, 2018(7): 94-99
  51. 范小军,杜长河,周源远,李亮,丰镇平.复合冲击和复合旋流冷却特性的对比研究. 工程热物理学报, 2018, 39(12): 2627-2633
  52. 杜长河, 范小军, 李亮, 丰镇平. 抽吸孔对旋流和冲击冷却流动传热特性的影响. 西安交通大学学报, 2017, 51(1): 19-24
  53. 杜长河, 范小军, 李亮, 丰镇平. 旋转半径和叶片安装角对动叶旋流冷却流动和传热特性的影响. 西安交通大学学报, 2017, 51(5): 37-42
  54. 范小军, 杜长河, 李亮, 邹佳生. 4种冷却结构对叶片前缘流动换热影响的比较研究. 西安交通大学学报, 2017, 51(7): 37-43
  55. 王杰枫, 范小军, 李森, 张翔, 李亮. 弯曲通道中凸、凹表面水膜流动特性的数值研究. 西安交通大学学报, 2017, 51(11): 22-28
  56. 李亮,薛太旭,李森. 考虑气动和湿汽损失综合影响的多级透平优化. 西安交通大学学报,201650(3): 22-28
  57. 陈宇佳, 杜长河, 李亮. 蒸汽冷却带肋矩形通道流动和换热特性数值研究. 西安交通大学学报, 2016, 50(3):62-67
  58. 杜长河,范小军,李亮,丰镇平.喷嘴角度和喷嘴数对旋流冷却流动与传热特性的影响. 西安交通大学学报,201650(4):76-80+146
  59. 范小军, 杜长河, 李亮, 李森. 气膜孔几何位置对旋流冷却流动与传热特性的影响. 西安交通大学学报, 2016, 50(7): 32-38
  60. 范小军,李亮,李森,张翔。平板和静叶表面气流水膜耦合流动特性的数值研究. 西安交通大学学报,201650(11)7-13
  61. 李亮,刘启凡,吴昕,张安学. 一种新的湿蒸汽湿度测量的微波加热法. 工程热物理学报,2016, 37(2): 272-276
  62. 杜长河,李森,李亮,丰镇平. 叶片前缘旋流蒸汽冷却流动和传热的数值研究. 西安交通大学学报,2015, 49(10): 72-78
  63. 杜长河,范小军,李亮,丰镇平.喷嘴长宽比和雷诺数对旋流冷却流动与传热特性的影响. 西安交通大学学报,2015, 49(12): 124-129+143
  64. 李森,李亮,杜长河. 球窝/球凸结构下的U型通道蒸汽冷却性能. 西安交通大学学报,2015, 49(9): 63-69
  65. 杜长河,李亮,丰镇平. 叶片蒸汽冷却耦合换热特性的数值研究.动力工程学报,201535(2)113-118+133
  66. 石慧,李亮,丰镇平. 污垢沉积影响叶片表面换热的研究. 航空动力学报,2015, 30(11): 2616-2622.
  67. 吴晓明, 杨建道, 李亮. 核电汽轮机中的湿蒸汽流动研究. 热力透平, 2015, 44(4): 233-238.
  68. 李瑜,宁德亮,李亮,李军. 汽轮机中湿汽损失的定量计算. 西安交通大学学报,2014, 48(1): 25-30
  69. 李亮,薛太旭,刘启凡,吴晓明,杨建道.湿蒸汽条件下空心静叶缝隙抽吸性能的试验研究.西安交通大学学报,2014, 48(11): 1-7
  70. 孙秀玲,李亮,马晓勇,李国君. 普朗特-迈耶流中湿空气非平衡凝结影响的研究. 空气动力学学报,201331(4): 425-429+448.
  71. 孙秀玲,马晓勇,李亮,李国君. RAE 2822翼型湿空气非平衡凝结流动的研究. 空气动力学学报,2013, 31(5): 592-597.
  72. 杨建道,游玮,李亮,吴晓明,程凯,王恭义,余德启,彭泽瑛. 核电汽轮机低压缸中平衡和非平衡凝结流动的对比研究. 热力透平, 2013,42(1):9-14
  73. 柴秀妮,李亮,陈群飞,丰镇平. 非平衡凝结流线曲率法通流程序开发及应用. 工程热物理学报,2012, 33(8): 1309-1312
  74. 李瑜,李亮,钟刚云,吴其林. 末级透平对低压缸气动和凝结特性的影响. 西安交通大学学报,201246(7): 16-20+86
  75. 孙秀玲,李亮,吴联为,李国君. 跨音速湿空气非平衡凝结流动的数值研究. 应用力学学报,2011, 28(5): 493-498
  76. 李亮,李瑜,吴晓明,陈红梅,李国君,丰镇平等. 汽轮机中湿蒸汽两相凝结流动研究. 热力透平, 2008, 37(4):235-239
  77. 孙秀玲,李亮,李国君. 湿空气凝结对ONERA M6机翼气动特性影响的数值研究. 空气动力学学报, 2010, 28(2): 143-148
  78. 徐小波,李瑜,吴其林,李亮. 某汽轮机中的湿蒸汽流动研究. 东方汽轮机,20101(1): 11-15.
  79. 孙秀玲,李亮,李国君. 翼型湿空气非平衡凝结流动的数值研究. 航空学报,2010, 31(8): 1546-1551.
  80. 吴晓明,李国君,李亮,丰镇平. 湿蒸汽凝结流中自激振荡模式的数值模拟. 动力工程,200929(8) 747-751.
  81. 费继友,李瑜,李亮. 甲烷、水蒸气与正壬烷气体的三相凝结流动数值分析. 石油化工高等学校学报,200821(3):1-4
  82. 张书平,吴革生,于志刚,李亮,白博峰. 含湿天然气超音速凝结研究. 工程热物理学报,2008, 29(11):1875-1878
  83. 李亮,丰镇平,李国君. 透平级内动静干涉对凝结特性影响的数值研究. 工程热物理学报, 2007, 28(suppl.1): 89-92. June, 2007
  84. 巫志华,李亮,丰镇平.低压汽机三维叶栅通道内湿蒸汽两相流动的数值模拟与分析. 工程热物理学报,2007, 28(5): 763-765
  85. 吴晓明,李亮,李国君,丰镇平. 基于双流体模型的湿蒸汽凝结流动三维数值模拟. 热能动力工程, 2007, 22(4): 367-370
  86. 吴晓明,李国君,丰镇平,李亮. SST k-ω-k_p两相湍流模型及其在湿蒸汽凝结流动数值模拟中的应用. 西安交通大学学报,2007, 41(5): 526-529+584
  87. 李亮, 程代京, 丰镇平,李国君. 汽轮机湿蒸汽级中凝结流动的三维数值分析. 工程热物理学报,200627(4):571-573
  88. 巫志华, 郭歌, 李亮, 丰镇平. 一种用于真实气体流动的数值计算方法. 西安交通大学学报. 2006, 40(5): 510-513
  89. 巫志华, 李亮, 丰镇平. 三维湿蒸汽自发凝结流动的数值模拟. 动力工程, 2006, 26(6): 814-817
  90. 巫志华,李亮,丰镇平. 湿蒸汽两相流动问题的耦合求解. 工程热物理学报,2005, 26(4): 578-580
  91. 陈红梅,李亮,丰镇平,李国君. 透平级中自发凝结及叶栅中非均质凝结流动的初步研究. 工程热物理学报,2005, 26(suppl.): 65-68
  92. 李亮,丰镇平,陈红梅,李国君. 凝结理论在汽轮机设计中应用的探讨. 热力透平,2005, 37(1): 36-40
  93. 张兄文,李国君,李军,李亮. 带控制片方柱绕流的非定常数值模拟. 应用力学学报,2005222):275-278.
  94. 陈红梅,李亮,丰镇平,李国君. 一维喷管中湿蒸汽非均质凝结流动研究. 工程热物理学报,2004, 25(3): 395-398
  95. 李亮, 丰镇平, 李国君. 湿蒸汽两相流中超临界加热引起的非定常凝结流动一维数值分析. 自然科学进展, 2003,13(2): 210-213
  96. 李亮, 丰镇平, 李国君. 叶片出气边形状对叶栅中湿蒸汽凝结流动影响的数值研究. 工程热物理学报, 2003, 24(5): 767-769.
  97. 丰镇平, 李亮, 李国君. 汽轮机湿蒸汽两相凝结流动数值研究的现状与进展. 上海汽轮机, 2002, 2: 1-10
  98. 程代京,李亮. S1/S2相对流面迭代法及其在汽轮机改型中的应用. 西安交通大学学报,200236(5):495-499
  99. 李亮,丰镇平,李国君. 平面叶栅中的湿蒸汽两相凝结流动数值模拟. 工程热物理学报, 2002, 23(3):309~311
  100. 李亮,丰镇平,李国君.一维喷管中存在自发凝结的跨音速湿蒸汽两相流动数值模拟.工程热物理学报, 2001, 22(6)703-705
  101. 李亮,李国君,丰镇平.湿蒸汽两相流动的数值方法及其在喷管中的应用. 西安交通大学学报, 2001, 35(11)1131-1134