[1] Muthulakshmi L A, Natesan U, Ferrer A V, et al. Impact assessment of nuclear power plant discharge on zooplankton abundance anddistribution in coastal waters of Kalpakkam, India[J].Ecological Processes, 2019, 8(1):1-10. [2] Jung Y H, Kim H J, Park H S. Thermal discharge effects on the species composition and community structure of macrobenthos in rocky intertidal zone around the taean thermoelectric power plant, korea[J]. Ocean and Polar Research, 2018, 40(2):59-67. [3] Gaeta M G, Samaras A G, Archetti R.Numerical investigation of thermal discharge to coastal areas: A casestudy in South Italy[J].Environmental Modelling & Software,2020,124:104596. [4] 华厦,王义刚,刘荣,等. 网格尺度对钦州湾水动力模拟影响研究[C]//中国海洋学会海洋工程分会.第十八届中国海洋(岸)工程学术讨论会论文集(下).北京:海洋出版社,2017:470-475. [5] 毛蒙玺,黄惠明,王义刚,等. 网格尺寸对河流水动力数值模拟的影响[J].水运工程,2018(3):135-142. MAO Mengxi, HUANG Huiming, WANG Yigang,et al.Influence of grid size on numerical simulation of river hydrodynamics[J].Port &Waterway Engineering, 2018(3):135-142. [6] 林凯荣,刘珊珊,陈华,等. DEM网格尺度对水文模拟影响的研究[J].水力发电,2007(12):12-14. LIN Kairong,LIU Shanshan,CHEN Hua,et al.Effects and study of digital elevation model mesh scale on hydrological modeling[J].Water Power, 2007(12):12-14. [7] 刘青娥,夏军,陈晓宏. 潮河流域TOPMODEL模型网格尺度研究[J].水文,2008(3):29-32. LIU Qinge,XIA Jun,CHEN Xiaohong.Study on mesh scale of TOPMODEL for chaohe river basin[J]. Journal of China Hydrology,2008(3):29-32. [8] 段金龙,李卫东,张学雷,等. 水体空间分布多样性分析的网格尺度研究[J].水文,2015,35(6):19-23. DUAN Jinlong,LI Weidong,ZHANG Xuelei,et al.Grid scale study in water spatial distribution diversity analysis[J]. Journal of China Hydrology, 2015,35(6):19-23. [9] 王长金,胡鹏. 网格尺寸及初始扰动对辫状河流演变模拟的影响[J].泥沙研究,2022,47(4):30-37. WANG Changjin,HU Peng.Influence of grid scale and initial disturbance on the process of numerical braid rivers[J].Journal of Sediment Research, 2022,47(4):30-37. [10] 崔贞,王珊,傅宗甫,等. 不同网格尺度对浮体水动力学性能的影响[J].水电能源科学,2016,34(12):101-105. CUI Zhen,WANG Shan,FU Zongfu,et al.Influence of mesh scale on hydrodynamic characteristics of floating body[J]. Water Resources and Power,2016,34(12):101-105. [11] 覃文洁,胡春光,郭良平,等. 近壁面网格尺寸对湍流计算的影响[J].北京理工大学学报,2006(5):388-392. QIN Wenjie,HU Chunguang,GUO Liangping,et al.Effect of near-wall grid size on turbulent flow solutions[J].Transactions of Beijing Institute of Technology,2006(5):388-392. [12] 周锟,胡进. 绕流直接数值模拟误差分析[J].力学与实践,2023,45(1):54-66. ZHOU Kun,HU Jin.Error in numerical simulation of external flow around an immserd body[J]. Mechanics in Engineering,2023,45(1):54-66. [13] 赵婉璐,郝瑞霞. 基于ECOMSED模型的湛江湾水道三维潮流数值模拟[J].海洋科学,2015,39(4):83-86. ZHAO Wanlu,HAO Ruixia.Three dimensional numerical imitation of tidal current in the Zhanjiang Bay channel based on ECOMSED model[J]. Marine Sciences,2015,39(4):83-86. [14] 曹颖,朱军政. 基于FVCOM模式的温排水三维数值模拟研究[J].水动力学研究与进展A辑,2009,24(4):432-439. CAO Ying,ZHU Junzheng.Numerical simulation of 3D cooling water based on FVCOM[J]. Chinese Journal of Hydrodynamics, 2009,24(4):432-439. [15] 段亚飞,赵懿珺,纪平,等. 温排水水槽试验与平面二维、准三维及三维数值模拟的比较[J].水力发电学报,2017,36(9):100-110. DUAN Yafei,ZHAO Yijun,JI Ping,et al.Tank experiment of cooling water discharge and its numerical simulations using 2D,quasi-3D and 3D models[J].Journal of Hydroelectric Engineering,2017,36(9):100-110. [16] Safavi S,Saghafian B,Hosseini A S.Characterizing flow pattern and salinity using the 3D MIKE 3 model: Urmia Lake case study[J].Arabian Journal of Geosciences,2020,13(3):115. [17] 李娜,娄安刚,张学庆,等. 基于MIKE3的渤海三维温盐数值模拟[J].海洋湖沼通报,2019(2):1-9. LI Na,LOU Angang,ZHANG Xueqing,et al.Three dimensional numerical simulation of temperature and salinity in the Bohai sea based on MIKE3[J]. Transactions of Oceanology and Limnology,2019(2):1-9. [18] 陆凡,沈良朵,高郁,等. 舟山绿色石化三维潮流特性数值研究[J].海洋学报,2022,44(5):134-147. LU Fan,SHEN Liangduo,GAO Yu,et al.Numerical study on three-dimensional tidal current characteristics of Zhoushan Green Petrochemical Company[J]. Haiyang Xuebao,2022,44(5):134-147. [19] Danush Hydraulic Institute. MIKE 21 & MIKE 3 FLOW MODEL FM Hydrodynamic and Transport Module Scientific Documentation [R].DHI,2016. [20] 宁波市海洋环境监测中心.三门核电项目水文泥沙测验综合分析报告(夏季)[R]. 2019. |