周晅毅

职称:教授

学位:博士

    国际期刊

    51. J.Zhu, X.Zhou*, H.Kikumoto, Source term estimation in the unsteady flow with dynamic mode decomposition, Sustainable Cities and Society, 115 (2024) 105843.

    50. F.Wang, X.Zhou*, H.Kikumoto, Detector configuration optimization method considering response time for spatial source parameter estimation in complex urban wind environment, Building and        Environment, 265 (2024) 111997.

    49. F.Wang, X.Zhou*, T.Okaze, Detector configuration optimization based on wind tunnel tests using normalized adjoint concentration gradient for urban spatial source parameters estimation, Building and Environment, 248 (2024) 111094.

    48. X.Zhou, L.Xin*, T.Zhang, M.Gu, Modified FAE method based on CFD simulation for predicting snowdrift on gable roofs, Cold Regions Science and Technology, 2024, 218, 104093.

    47. X.Zhou, H.Chen, Y.Wu*, T.Zhang, Simulation of roof snow loads based on a multi-layer snowmelt model: Impact of building heat transfer. Building Simulation, Building Simulation, 2024, 17, 907-932.

    46. X.Zhou, T.Zhang*, Numerical simulations of wind-induced snow redistributions on large-span flat roofs: Development of snow transport along roof span, Journal of Wind Engineering and Industrial Aerodynamics, 2024, 251, 105802.

    45. T.Zhang, X.Zhou, Z.Liu*, Numerical simulation of rime ice accretion on a three-dimensional wind turbine blade using a Lagrangian approach, Frontiers of Structural and Civil Engineering, 2023, 17(12), 1895-1906.

    44.H.Ma, X.Zhou, J.Huang*, Effect of ventilation on thermal and humidity environment of the underground utility tunnel in the plum rain season in southern China: Field measurement and CFD simulation, Underground Space, 2023, 13, 301-315.

    43.J.Zhou, X.Zhou, B.Cong*, et al. Numerical study of the convective heat transfer coefficient for steel column surrounded by localized fires[J]. Fire Safety Journal, 2023: 103987.

    42.J.Zhou, X.Zhou*, B.Cong, et al. Comparison of different CFD-FEM coupling methods in advanced structural fire analysis[J]. International Journal of Thermal Sciences, 2023, 193: 108465.

    41.T.Zhang, X.Zhou*, Numerical simulations of snow saltation over flat terrain: Development of snow transport, Journal of Wind Engineering and Industrial Aerodynamics, 2023, 240, 105472.

    40.Y.Peng, S.Liu, S.Wang, W.Zhao, J.Zhou, X.Zhou*, Reliability assessment and performance improvement of long-span roof structure subjected to coupled wind-snow multi-hazard, Cold Regions Science and Technology, 214(2023), 103958, DOI: 10.1016/j.coldregions.2023.103958.

    39. X.Zhou*, T.Zhang, A review of computational fluid dynamics simulations of wind-induced snow drifting around obstacles, Journal of wind engineering and industrial aerodynamics, 234(2023),105350, DOI: 10.1016/j.jweia.2023.105350. 

    38. X.Zhou, T.Zhang, Z.L*, M.Gu, An Eulerian-Lagrangian snow drifting model for gable roofs considering the effect of roof slope, Journal of wind engineering and industrial aerodynamics, 234(2023),105334, DOI: 10.1016/j.jweia.2023.105334. 

    37. X.Zhou, T.Zhang, Z.L*, M.Gu, A study of snow drifting on monoslope roofs during snowfall: Wind tunnel test and numerical simulation, Cold Regions Science and Technology, 206(2023),103731, DOI: 10.1016/ j.coldregions.2022.103731. 

    36. J.Zhu, X.Zhou, B.Cong*, H. Kikumoto, Estimation of the point source parameters by the adjoint equation in the time-varying atmospheric environment with unknown turn-on time, Building and Environment, 230 (2023) 110029, DOI: 10.1016/ j.buildenv.2023.110029.

    36. J.Zhou, X.Zhou*, B.Cong, et al. Simulation of steel beam under ceiling jet based on a wind-fire-structure coupling model[J]. Front. Struct. Civ. Eng. 17, 78-98 (2023).

    35.Y.Wu, X.Zhou*, Y.Zhang, M.Gu, Simulation and statistical analysis of ground snow loads based on a multi-layer snow accumulation and melt model, Structural Safety, 100 (2023) 102295, DOI: 10.1016/j.strusafe.2022.102295. 

    34. K.Zhang, X.Zhou, B.Cong*, The effect of relative humidity on vapor dispersion of liquefied natural gas: A CFD simulation using three phase change models, Journal of wind engineering and industrial aerodynamics, 230(2022),105181, DOI: 10.1016/j.jweia.2022.105181. 

    33. F.Wang, X.Zhou*, H.Kikumoto, Improvement of optimization methods in indoor time-variant source parameters estimation combining unsteady adjoint equations and flow field information, Building and Environment, 226 (2022) 109710, DOI: 10.1016/j.buildenv.2022.109710.

    32. F.Wang, X.Zhou, J.Huang*, H.Wang, H.Kikumoto, C.Deng, Natural gas leakage estimation in underground utility tunnels using Bayesian inference based on flow fields with gas jet disturbance, Process Safety and Environmental Protection, 2022, 165, 532-544. 

    31. X.Zhou, L.Xin, S.Qiang*, M.Gu, Probabilistic study of snow loads on flat roofs considering the effects of wind at representative sites in China, Structural Safety, 99 (2022) 102242, DOI: 10.1016/j.strusafe.2022.102242.

    30. L.Xin, X.Zhou*, M.Gu, Wind tunnel test and CFD simulation of the near-roof wind speed and friction velocity on gable roofs, Journal of wind engineering and industrial aerodynamics, 2022, 225, DOI10.1016/j.jweia.2022.105009. 

    29. Z.Liu, X.Zhou*, M.Gu, A numerical model for snow drifting simulations on flat roofs using Lagrangian approach, Journal of wind engineering and industrial aerodynamics, 2022, 222, DOI: 10.1016/j.jweia.2022.104922.

    28. H.Ma, X.Zhou*, Y.Tominaga, M.Gu, CFD simulation of flow fields and pollutant dispersion around a cubic building considering the effect of plume buoyancies, Building and Environment, 208 (2022) 108640, DOI10.1016/j.buildenv.2021.108640.

    27. X.Zhou, Z.Liu, W.Ma*, K.Kosugi, M.Gu, Experimental investigation of snow drifting on flat roofs during snowfall: Impact of roof span and snowfall intensity, Cold Regions Science and Technology, 2021, 190, DOI:10.1016/j.coldregions.2021.103356.

    26. X.Zhou, A.Ying, B.Cong*, H.Kikumoto, R.Ooka, L.Kang, H.Hu, Large eddy simulation of the effect of unstable thermal stratification on airflow and pollutant dispersion around a rectangular building, Journal of wind engineering and industrial aerodynamics, 2021, 211, DOI:10.1016/j.jweia.2021.104526.

    25. S.Qiang, X.Zhou*, M.Gu, L.Kang, A novel snow transport model for analytically investigating effects of wind exposure on flat roof snow load, Journal of wind engineering and industrial aerodynamics, 2021, 210, DOI: 10.1016/j.jweia.2020.104505. 

    24. X.Zhou, T.Zhang, W.Ma, Y.Quan*, M.Gu, L.Kang, Y.Yang, CFD simulation of snow redistribution on a bridge deck: Effect of barriers with different porosities, Cold Regions Science and Technology, 2021, 181.

    23. X.Zhou*, Y.Zhang, L.Kang, M.Gu, RANS CFD simulations can be successfully used for simulating snowdrift on roofs in a long period of snowstorm. Building Simulation, 2020, 13, 1157-1163.

    22. S.Qiang, X.Zhou*, K.Kosugi, M.Gu, A study of snow drifting on a flat roof during snowfall based on simulations in a cryogenic wind tunnel, Journal of wind engineering and industrial aerodynamics, 2019, 188, 269-279.

    21. X.Zhou, Y.Zhang, L.Y.Kang*, M.Gu, CFD simulation of drifting snow loads on gable roofs: impact of roof slope, Journal of wind engineering and industrial aerodynamics, 2019, 185, 16-32.

    20. X.Zhou, Y.Zhang, M.Gu*, Coupling a snowmelt model with a snowdrift model for the study of snow distribution on roofs, Journal of wind engineering and industrial aerodynamics, 2018, 182, 235-251.

    19. L.Kang, X.Zhou*, T.Hooff, B. Blocken, M.Gu, CFD simulation of snow transport over flat, uniformly rough, open terrain: impact of physical and computational parameters, Journal of wind engineering and industrial aerodynamics, 2018, 177, 213-226.

    18. X.Zhou, G.Zu*, M.Gu, J.Hu, LES and Wind Tunnel Test on Friction Velocity on Roof Surfaces, Cold Regions Science and Technology, 2018, 151, 109-118.

    17. S.Qiang, X.Zhou*, M.Gu, Research on reliability of roof structures subjected to snow loads at representative sites in China, Cold Regions Science and Technology, 2018, 150, 62-69.

    16. X.Zhou, S.Qiang, Y.Peng, M.Gu*, Wind tunnel test on responses of a lightweight roof structure under joint action of wind and snow loads, Cold Regions Science and Technology, 2016, 132, 19-32.

    15. X.Zhou, L.Kang, X.Yuan, M.Gu*, Wind tunnel test of snow redistribution on flat roofs, Cold Regions Science and Technology, 2016, 127, 49-56. 

    14. X.Zhou, L.Kang, M.Gu*, L.Qiu, J.H.Hu, Numerical simulation and wind tunnel test for redistribution of snow on flat roofs, Journal of wind engineering and industrial aerodynamics, 2016, 153, 92-105.

    13. W.Sun, M.Gu, X.Zhou*, Universal Equivalent Static Wind Loads of Fluctuating Wind Loads on Large-Span Roofs Based on POD Compensation, Advances in Structural Engineering, 2015, 18(9) 1443-1459.

    12. X.Zhou, J.Li, M.Gu*, L.Sun, A new simulation method on sliding snow load on sloped roofs, Natural Hazards, 2015, 77(1) 39-65.

    11. X.Zhou, Y.Lin, M.Gu*, Optimization of multiple tuned mass dampers for large-span roof structures subjected to wind loads, Wind and Structures, 2015, 20(3) 363-388.

    10. X.Zhou, J.Hu, M.Gu*, Wind tunnel test of snow loads on a stepped flat roof using different granular materials, Natural Hazards, 2014, 74(3) 1629-1648.

    09. X.Zhou, M.Gu*, G.Li, Constrained Least-Squares Method for Computing Equivalent Static Wind Loads of Large-span Roofs, Advances in Structural Engineering, 2014, 17(10) 1497-1515.

    08. X.Zhou, Y.Zhang, M.Gu*, Simulation Method of sliding Snow Load on Roofs and its application in Some Representative Regions of China, Natural Hazards,2013, 67(2) 295-320.

    07.X.Zhou, Z.Han, M.Gu*, A.Zhang, W.Zhang, W.Fang, Research on Wind-induced Responses of a Large-scale Membrane Structure, Earthquake Engineering and Engineering Vibration, 2013, 12(2) 297-305.

    06. P.Huang, X.Zhou, M.Gu*, Experimental study of wind loads on cylindrical reticulated shells, Applied Mathematics and Mechanics (English Edition), 2013, 34(3) 281-296.

    05. X.Zhou, M.Gu*, G.Li, Grouping Response Method for Equivalent Static Wind Loads Based on Modified LRC Method, Earthquake Engineering and Engineering Vibration, 2012, 11(1) 107-119.

    04. X.Zhou, P.Huang, M.Gu*, F.Mi, Wind Loads and Responses of Two Neighboring Dry Coal Sheds, Advances in Structural Engineering, 2011, 14(2) 207-221.

    03. X.Zhou, M.Gu*, An Approximation Method for Computing the Dynamic Responses and Equivalent Static Wind Loads of Large-span Roof Structures , International Journal of Structural Stability and Dynamics, 2010, 10(5) 1141-1165.

    02. X.Zhou, P.Huang, M.Gu*, L.Zhu, H.M. Pan, Wind loads and wind-induced responses of Guangzhou New TV Tower, Advances in Structural Engineering, 2010, 13(4) 707-726.

    01. M.Gu*, X.Zhou, An approximation method for resonant response with coupling modes of structures under wind action, Journal of wind engineering and industrial aerodynamics, 2009, 97(11-12) 573-580.


     

    国际会议

    31.Y. Wu, X. Zhou, Simulation of roof snow loads considering building heat transfer, Proceedings of the 9th international conference on snow engineering, 3-5 June 2024, Shanghai, China, 171-178, organized by Tongji University.

    30. T. Zhang, X. Zhou, CFD simulations of snow drifting on large-span flat roofs, Proceedings of the 9th international conference on snow engineering, 3-5 June 2024, Shanghai, China, 107-114, organized by Tongji University.

    29. S. Ding, X. Zhou, A study of combination factor of wind and snow loads on photovoltaic (PV) panels based on characterization of joint wind-snow hazard:Urumqi as a case study, Proceedings of the 9th international conference on snow engineering, 3-5 June 2024, Shanghai, China, 293-300, organized by Tongji University.

    28. X.Zhou, T.Zhang, Wind tunnel simulations of snow transport on a flat roof during snowfall, The 16th International Conference on Wind Engineering, August 27-31, 2023, Florence, Italy, organized by Università degli Studi di Firenze and Interuniversity Research Centre on Building Aerodynamics and Wind Engineering.

    27. L.Xin, X.Zhou, M.Gu, Modified FAE method based on CFD simulation for predicting snowdrift on gable roofs, The 16th International Conference on Wind Engineering, August 27-31, 2023, Florence, Italy, organized by Università degli Studi di Firenze and Interuniversity Research Centre on Building Aerodynamics and Wind Engineering.

    26. J.Zhu, X.Zhou, The influence of turn-on time of source on the estimation of source location and release rate in time-varying flow, The 16th International Conference on Wind Engineering, August 27-31, 2023, Florence, Italy, organized by Università degli Studi di Firenze and Interuniversity Research Centre on Building Aerodynamics and Wind Engineering. 

    25. F.Wang, X.Zhou, Spatial source parameters estimation in urban environment using optimization method combined with adjoint equation simulated via large eddy simulation, The 16th International Conference on Wind Engineering, August 27-31, 2023, Florence, Italy, organized by Università degli Studi di Firenze and Interuniversity Research Centre on Building Aerodynamics and Wind Engineering.

    24. T.Zhang, X.Zhou, CFD simulations of snow saltation on flat terrain, 16th International Conference on Wind Engineering, August 27-31, 2023, Florence, Italy, organized by Università degli Studi di Firenze and Interuniversity Research Centre on Building Aerodynamics and Wind Engineering.

    23. H.Ma, X.Zhou, CFD simulation of forced convective heat transfer in street canyon: effect of wind direction and tree planting, August 27-31, 2023, Florence, Italy, organized by Università degli Studi di Firenze and Interuniversity Research Centre on Building Aerodynamics and Wind Engineering. 

    22. Y.Wu, X.Zhou, Ground Snow Pressure Evaluation based on Energy Balance Multi-layer Snowmelt Model, JSSI & JSSE Joint Conference on Snow and Ice Research-2023 in Koriyama雪氷研究大会(2023.郡山)講演要旨集, September 3-6, 2023, 郡山Koriyama, 日本Japan, 70-70, organized by 日本雪氷学会The Japanese Society of Snow and ice and Japan Society for Snow Engineering日本雪工学会.

    21. Shan Ding, Xuanyi Zhou, Wind and snow load combination based on snowmelt model: Urumqi as a case study, JSSI & JSSE Joint Conference on Snow and Ice Research-2023 in Koriyama雪氷研究大会(2023.郡山)講演要旨集, September 3-6, 2023, 郡山Koriyama, 日本Japan, 69-69, organized by 日本雪氷学会The Japanese Society of Snow and ice and Japan Society for Snow Engineering日本雪工学会.

    20. X.Zhou, Y.Zhang, M.Gu, L.Kang, CFD simulation of wind-induced snow redistribution on gable roofs, JSSI & JSSE Joint Conference on Snow and Ice Research-2019 in Yamagata雪氷研究大会(2019.山形)講演要旨集, September 8-11, 2019, 山形Yamagata, 日本Japan, 33-33, organized by 日本雪氷学会The Japanese Society of Snow and ice and Japan Society for Snow Engineering日本雪工学会.

    19. Z.Liu, X.Zhou, M.Gu, 3D numerical simulation of rime ice on wind turbine blade, JSSI & JSSE Joint Conference on Snow and Ice Research-2019 in Yamagata雪氷研究大会(2019.山形)講演要旨集, September 8-11, 2019, 山形Yamagata, 日本Japan, 33-33, organized by 日本雪氷学会The Japanese Society of Snow and ice and Japan Society for Snow Engineering日本雪工学会.

    18. Z.Liu, X.Zhou, M.Gu, H.Ma, 3D numerical simulation of rime ice on wind turbine blade, The 15th International Conference on Wind Engineering, September 1-6, 2019, Beijing, China, 307-308, organized by Beijing Jiaotong University and Tongji University.

    17. X.Zhou, Y.Zhang, M.Gu, L.Kang, CFD simulation of wind-induced snow redistribution on gable roofs, The 15th International Conference on Wind Engineering, September 1-6, 2019, Beijing, China, 611-612, organized by Tongji University and Beijing Jiaotong University.

    16. X.Zhou, Y.Zhang, M.Gu, Simulation of snow load based on a multi-layer snowmelt model, International Workshop on Wind-Related Disasters and Mitigation, 11-14 March 2018, Sendai, Japan, 71-71, organized by Organizing Committee of WRDM.

    15. X.Zhou, J.Li, P.Huang, M.Gu, L.Sun, A new method of predicting slide snow load for sloped roofs, Snow Engineering Ⅷ, 14-17 June 2016, Nantes, France, 174-178.

    14. L.Kang, X.Zhou, M.Gu, A new method for predicting snowdrift on flat roofs, Snow Engineering Ⅷ, 14-17 June 2016, Nantes, France, 137-141.

    13. S.Qiang, X.Zhou, M.Gu, Research on reliability of roof structures designed by Chinese codes, Snow Engineering Ⅷ, 14-17 June 2016, Nantes, France, 101-105.

    12. X.Zhou, J.Li, M.Gu, A prediction method of slide snow/ice load applied to roofs, Proceedings of the 16th International Workshop on Atmospheric Icing of Structures, IWAIS 2015, 28 June -3 July 2015, Uppsala, Sweden, organized by WindEn Company.

    11. L.Kang, X.Zhou, M.Gu, Influence of Roof Slope on Snow Redistribution of Gable Roof, The 6th International Symposium on Computational Wind Engineering, 8-12 June 2014, Hamburg, Germany, 114-115.

    10. X.Zhou, Y.Zhang, M.Gu, Simulation on Sliding Snow Load on Roofs, 1st International Conference on Computational Engineering and Science for Safety and Environmental Problems (COMPSAFE 2014), 13-16 April 2014, Sendai, Japan, 245-247.

    09. X.Zhou, M.Gu, G.Li, ESWL for Large-span Roof Based on Grouping Response Method, The Eighth Asia-Pacific Conference on Wind Engineering, 10-14 December 2013, Chennai, India, 3-6.

    08. X.Zhou, X.Li, M.Gu, etc., A New Two-equation Model for Numerical Simulation on Snow Drifting, Snow Engineering 7, 6-8 June 2012, Fukui, Japan.

    07. X.Zhou, Z.Han, M.Gu, P.Huang, Y.Quan, Analysis of Wind-induced Responses of a Large-scale Membrane Structure, IABSE-IASS Symposium London 2011, 20-23 September 2011, London, U.K., organized by the UK Group of IABSE and IASS with Brintex Events, 154-154.

    06. X.Zhou, M.Gu, G.Li, Application Research of Constrained Least-Squares Method in Computing Equivalent Static Wind Loads, The 13th International Conference on Wind Engineering, 10-15 July 2011, Amsterdam, Netherlands, organized by the Dutch-Flemish Wind Engineering Association.

    05. K.Yan, X.Zhou, M.Gu,M. Kaspershki, wind-induced snow load simulation on gable roof, The Fifth International Symposium on Computation Wind Engineering, May 23-27 2010, North Carolina, organized by United States Association for Wind Engineering Society.

    04. X.Zhou, M.Gu, F.Mi, P.Huang, Analysis of Wind-induced Responses of Dry Coal Shed Under Interference Condition, The 4th International Conference on Advances in Wind and Structures, 29-31 May 2008, Jeju, Korea, 1855-1863.

    03. X.Zhou, M.Gu, Equivalent Static Wind Loads of Large-span Roof Structures, The 12th International Conference on Wind Engineering, 1-6 July 2007, Cairns, Australia, 431-438.

    02. X.Zhou, M.Gu, Numerical Simulation of Snow Drift on the Surface of a large-span Roof Structure, The Fourth International Symposium on Computation Wind Engineering, July 2006, Yokohama, Japan, 889-892.

    01. X.Zhou, M.Gu, Prediction of Wind Load on Large-span Roofs Using Artificial Neural Networks, Proceedings of the Sixth Asia-Pacific Conference on Wind Engineering, September 2005, Seoul, KOREA, 1682-1691.


     

    中文期刊

    61. 辛林桂, 周晅毅, 顾明, 平屋面摩擦速度的数值模拟研究, 工程力学, 2024, 41(2) 151-159.

    60. 吴悦, 周晅毅, 基于能量平衡融雪模型的地面雪压评估以及与日本规范评估方法的比较,土木工程学报, https://doi.org/10.15951/j.tmgcxb.23070581.

    59. 张天歌, 周晅毅, 顾明, 不同护栏透风率下桥面雪飘移的数值模拟, 工程力学, 2023, 40(3) 19-25.

    58. 周晅毅, 马慧心, 顾明, 考虑羽流浮力影响的高层建筑周围污染物扩散数值模拟, 同济大学学报, 2022, 50(6) 767-775.

    57. 朱建杰, 周晅毅, 顾明, 基于贝叶斯推断的时变流场下污染源反演, 同济大学学报, 2022, 50(6) 802-811.

    56. 周晅毅, 王富玉, 杨流阔, 顾明, 基于Nelder-Mead算法的机器人主动嗅觉室内时变污染源定位, 同济大学学报, 2022, 50(6) 812-820.

    55. 周晅毅, 李景, 孙鲁鲁, 顾明, 超高层建筑电梯热压分布特性模拟研究, 建筑结构, 2018, 48(9)67-71, 61.

    54. 周晅毅, 胡学富, 顾明, 考虑摩擦速度修正的风致积雪重分布模拟方法研究, 工程力学, 2017, 34(10) 19-25.

    53. 周晅毅, 谭敏海, 晏克勤, 顾明, 胡学富, 风致积雪重分布的拉格朗日方法与现场实测研究, 工程力学, 2017, 34(2) 21-27.

    52. 康路阳, 周晅毅,顾明, 考虑积雪休止角的屋面积雪漂移数值模拟方法, 同济大学学报, 2016, 44(4) 11-15.

    51. 周晅毅, 祖公博, 顾明, TTU标准模型表面风压大涡模拟及风洞试验的对比研究, 工程力学, 2016, 33(2) 104-110.

    50. 周晅毅, 林勇建, 顾明, 大跨屋盖结构MTMD风振控制最优性能研究, 振动工程学报, 2015, 28(2) 277-284.

    49. 周晅毅, 刘长卿, 顾明, 谭敏海, 拉格朗日方法在风雪运动模拟中的应用, 工程力学, 2015, 32(1) 36-42.

    48. 周晅毅, 张运清, 顾明, 孙鲁鲁, 屋面滑移雪荷载的简化计算方法, 同济大学学报, 2014, 42(12) 1833-1839.

    47. 周晅毅, 张运清, 顾明, 建筑屋面滑移雪荷载的模拟方法研究, 工程力学, 2014, 31(6) 190-196.

    46. 胡金海, 周晅毅, 顾明, 不同规范中雪荷载作用下门式刚架静力响应和稳定性研究, 钢结构, 2013, 28(5)47-53.

    45. 林勇建, 周晅毅, 顾明, 柱面网壳结构MTMD风振控制研究, 结构工程师, 2013, 29(2)114-121.

    44. 周晅毅, 刘长卿, 顾明, 跃移雪颗粒运动特性的数值模拟研究, 同济大学学报, 2013, 41(4) 522-529, 546.

    43. 周晅毅, 李雪峰, 顾明, 张艳萍, 风吹雪数值模拟的两方程模型方法, 空气动力学学报, 2012, 30(5) 640-645, 652.

    42. 孙五一, 周晅毅, 顾明, 基于补偿方法的大跨屋盖脉动风等效静力风荷载, 振动工程学报, 2011, 24(6) 658-663.

    41. 李雪峰, 周晅毅, 顾明, 风雪运动数值模拟中自保持平衡边界条件研究, 空气动力学学报, 2011, 29(6) 765-769.

    40. 黄友钦, 顾明, 周晅毅, 积雪漂移对空间结构动力稳定性的影响, 振动与冲击, 2011, 30 (2) 124-129.

    39. 周晅毅, 李刚, POD结合薄板样条插值法在风压预测中的应用, 建筑结构, 2011, 41(6) 98-102, 109.

    38. 黄友钦, 顾明, 周晅毅, 以动力稳定为目标的空间结构等效静力风荷载, 同济大学学报, 2011, 39(5) 637-642.

    37. 韩志惠, 周晅毅, 顾明, 张安安, 张伟育, 方卫, 世博轴阳光谷结构风致响应分析及频域时域方法计算结果比较, 振动与冲击, 2011, 30 (5) 230-235.

    36. 孙五一, 周晅毅, 顾明, 基于风场模态补偿的大跨屋盖脉动风等效静力风荷载, 工程力学, 2011, 28 (4) 96-101.

    35. 周晅毅, 顾明, 臧健, 全涌, 晏克勤, 深圳机场T3航站楼风压特性研究, 建筑结构, 2011, 41(1)122-125.

    34. 李雪峰, 李洪求, 周晅毅, 某大型体育场屋盖风致积雪飘移的数值模拟, 结构工程师, 2010, 26(6)64-69.

    33. 周晅毅, 顾明, 李刚, 加权约束最小二乘法计算等效静力风荷载, 同济大学学报, 2010. 38(10) 1403-1408.

    32. 周晅毅, 晏克勤, 顾明, 冯永异, 某机场航站楼屋面风荷载特性研究, 振动与冲击, 2010, 29 (8) 224-227, 254.

    31. 李雪峰, 周晅毅, 顾明, 植松康, 立方体模型周边风致积雪飘移的数值模拟研究, 同济大学学报, 2010. 38(8) 1135-1140.

    30. 周晅毅, 顾明, 米福生, 黄鹏, 干扰效应下煤棚结构风致响应研究, 同济大学学报, 2010, 38(6) 817-826.

    29. 周晅毅, 顾明, 李刚, 基于修正LRC的响应分组法求解等效静力风荷载, 振动工程学报, 2010, 23(2) 158-166.

    28. 韩志惠, 周晅毅, 顾明, 张伟育, 世博轴阳光谷大型钢结构风致线性和非线性响应比较, 振动与冲击, 2009, 28 (12) 155-159, 209.

    27. 周晅毅, 顾明, 米福生, 黄鹏, 干扰条件下煤棚结构风致干扰特性研究, 振动工程学报, 2009, 22(6) 652-658.

    26. 郑德乾, 顾明, 周晅毅, 张伟育等, 世博轴膜面平均风压的数值模拟研究, 建筑结构学报, 2009, 30 (5) 212-219.

    25. 周晅毅, 顾明, 朱乐东, 黄鹏, 广州新电视塔模型测力风洞试验及风致响应研究 Ⅱ: 风致响应分析, 土木工程学报, 2009, 42(7)14-20.

    24. 顾明, 黄鹏, 周晅毅, 朱乐东, 广州新电视塔模型测力风洞试验及风致响应研究 I: 风洞试验, 土木工程学报, 2009, 42(7)8-13.

    23. 周晅毅, 顾明, 黄友钦, 商承志, 基于非定常风荷载的大跨体育场挑篷结构风致响应, 同济大学学报, 2008, 36(11)1490-1495.

    22. 周晅毅, 顾明, 马文勇, 范重, 复杂多塔结构风致响应研究, 振动工程学报, 2008, 21(4) 349-353.

    21. 周晅毅, 顾明, 风致积雪漂移堆积效应的研究进展, 工程力学, 2008, 25 (7) 5-10, 17.

    20. 李雪峰, 周晅毅, 顾明, 北京南站屋面雪荷载分布研究, 建筑结构, 2008, 38(5)109-112.

    19. 韩志惠, 周晅毅, 顾明, 某建筑顶部装饰幕墙结构的风荷载及风致抖振响应计算, 振动与冲击, 2008, 27 (5) 40-43, 172.

    18. 周晅毅, 顾明, 李雪峰, 大跨度屋盖表面风致雪压分布规律研究, 建筑结构学报, 2008, 29 (2) 7-12.

    17. 周晅毅, 顾明, 李亚明, 周晓峰, 某大型博物馆结构风致响应分析, 振动与冲击, 2008, 27(2)25-28, 33, 173.

    16. 周晅毅, 顾明, 朱忠义, 黄崑, 首都国际机场3号航站楼屋面雪荷载分布研究, 同济大学学报, 2007, 35(9)1193-1196.

    15. 周晅毅, 黄鹏, 顾明, 受扰高层建筑的风致响应分析, 土木工程学报, 2007, 40(8)16-21.

    14. 米福生, 周晅毅, 顾明, 柱面网壳结构风致抖振响应研究, 振动与冲击, 2007, 26(7)32-35, 39.

    13. 周晅毅, 黄鹏, 顾明, 上海铁路南站屋盖表面风压特性试验研究, 建筑结构, 2007, 37(2)118-120.

    12. 周晅毅, 顾明, 气动总管对输入信号气动平均性能的试验研究, 同济大学学报, 2007, 35(1)32-36.

    11. 顾明, 周晅毅, 大跨度屋盖结构等效静力风荷载方法及应用, 建筑结构学报, 2007, 28 (1) 125-129.

    10. 顾明, 周晅毅, 黄鹏, 大跨屋盖结构风致抖振响应研究, 土木工程学报, 2006, 39 (11) 37-42.

    09. 周晅毅, 顾明, 大跨度屋盖结构考虑模态耦合的抖振共振响应分析方法, 振动工程学报, 2006, 19 (2) 179-183.

    08. 周晅毅, 顾明, 上海铁路南站屋盖结构风致抖振响应参数分析, 同济大学学报, 2006, 34 (5) 574-579.

    07. 周晅毅, 顾明, 风洞实验中多通道测压管路系统的参数分析, 同济大学学报, 2005, 33(8)1001-1006.

    06. 顾明, 黄鹏, 周晅毅, etc, 北京首都机场3号航站楼风荷载和响应研究, 土木工程学报, 2005, 38 (1) 40-44.

    05. 周晅毅, 顾明, 并联管道耗散模型的理论研究, 振动与冲击, 2004, 23(3)79-82.

    04. 王勇军, 周晅毅, 顾明, 集装箱起重机斜撑杆风振响应分析, 结构工程师, 2004, 271-279. (增刊)

    03. 顾明, 周晅毅, 神经网络方法在大跨度屋面风压研究中的应用, 工程力学, 2003, 20(4) 99-103.

    02. 周晅毅, 顾明, 单通道测压管路系统的优化设计, 同济大学学报, 2003, 31(7) 798-802.

    01. 周晅毅, 顾明, 大跨度屋盖表面风压系数的试验研究, 同济大学学报, 2002, 30(12) 1423-1428.


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