èŠ‚ç‚¹æ–‡çŒ®

è¿‘å²¸æ¤è¢«å¯¹æ³¢æµªè¡°å‡çš„äºŒç»´Boussinesqæ–¹ç¨‹æ•°å€¼ç ”ç©¶

Numerical simulation for wave attenuation by nearshore vegetation based on horizontal two-dimensional Boussinesq equation

æŽ¨è CAJä¸‹è½½
PDFä¸‹è½½
ä¸æ”¯æŒè¿…é›·ç‰ä¸‹è½½å·¥å…·ï¼Œè¯·å–æ¶ˆåŠ é€Ÿå·¥å…·åŽä¸‹è½½ã€‚

ã€ä½œè€…ã€‘ æ¡‘ç¥Žä¼¦ï¼› èµµæ´‹ï¼› å™æ˜Šï¼› åˆ˜å¿ æ³¢ï¼› åˆ˜å‹‡ï¼›

ã€Authorã€‘ SANG Yilun;ZHAO Yang;SUN Hao;LIU Zhongbo;LIU Yong;College of Engineering, Ocean University of China;College of Transportation Engineering, Dalian Maritime University;

ã€é€šè®¯ä½œè€…ã€‘ èµµæ´‹;

ã€æ‘˜è¦ã€‘ è¿‘å²¸æ¤è¢«èƒ½è¾ƒæ˜¾è‘—çš„è€—æ•£æ³¢æµªèƒ½é‡ï¼Œä»Žè€Œå½±å“å’Œæ”¹å˜è¿‘å²¸æ°´åŠ¨åŠ›è¿‡ç¨‹ã€‚åŸºäºŽæ°´å¹³äºŒç»´Boussinesqåž‹æ°´æ³¢æ–¹ç¨‹ï¼Œåœ¨æ¨¡åž‹ä¸å¼•å…¥æ¤è¢«è€—æ•£é¡¹æ¥è€ƒè™‘æ¤è¢«å¯¹æ³¢æµªçš„è¡°å‡æ•ˆåº”ï¼Œå»ºç«‹äº†æ•°å€¼æ¨¡åž‹ç ”ç©¶æ³¢æµªä¼ æ’ç»è¿‡æ¤è¢«åŒºåŸŸçš„æ¼”åŒ–è§„å¾‹ï¼Œå¹¶é‡ç‚¹åˆ†æžè¿‘å²¸æ°´æ·±åœ°å½¢å˜åŒ–çš„å½±å“ã€‚åˆ©ç”¨æ–‡çŒ®ä¸çš„ç‰©ç†æ¨¡åž‹è¯•éªŒæ•°æ®ï¼ŒçŽ‡å®šæ¤è¢«æ‹–æ›³åŠ›ç³»æ•°ï¼Œå¹¶éªŒè¯æ•°å€¼æ¨¡åž‹çš„åˆç†æ€§ã€‚é€šè¿‡æ•°å€¼ç®—ä¾‹ï¼Œç ”ç©¶ä¸åŒåˆ†å¸ƒå¯†åº¦å’Œé«˜åº¦çš„æ¤è¢«å¯¹æ³¢æµªçš„è€—æ•£ä½œç”¨ï¼Œå¹¶è®¨è®ºå¹³åº•å’Œåœ†å½¢æµ…æ»©åœ°å½¢ä¸Šä¸åŒå‘¨æœŸçš„æ³¢æµªç»è¿‡æ¤è¢«åŒºåŸŸçš„è¡°å‡å¹…åº¦ã€‚æ•°å€¼åˆ†æžç»“æžœè¡¨æ˜Žï¼šå½“æ³¢æµªä¼ æ’ç»è¿‡æœ‰æ¤è¢«è¦†ç›–çš„å¹³åº•åœ°å½¢åŒºåŸŸæ—¶ï¼Œæ¤è¢«ä¼šå¼•èµ·æ³¢èƒ½è€—æ•£ï¼Œéšç€æ¤è¢«åˆ†å¸ƒå¯†åº¦çš„å¢žå¤§ï¼Œæ¤è¢«çš„æ³¢èƒ½è€—æ•£æ•ˆåº”éšä¹‹å¢žå¼ºï¼›åœ†å½¢æµ…æ»©åœ°å½¢ä¼šå¯¼è‡´æµ…æ»©åŽå½¢æˆæ³¢æµªè¾èšï¼Œé™ä½Žæ¤è¢«çš„æ¶ˆæµªæ•ˆæžœï¼Œæ¤æ—¶å¢žå¤§æ¤è¢«å¯†åº¦èƒ½å¤Ÿæœ‰æ•ˆé™ä½Žæ³¢æµªè¾èšå½±å“ã€‚æ›´å¤š è¿˜åŽŸ

ã€Abstractã€‘ Nearshore vegetation can dissipate wave energy and change the hydrodynamic processes significantly. Based on the horizontal two-dimensional Boussinesq-type water wave equation, vegetation dissipation was introduced into the model. The attenuation effect of vegetation on waves was considered, and a numerical model(BW model) was established to study the evolution of wave propagation through vegetation regions, especially taking into account the influence of nearshore water depth and topography changing. Through physical model test data in the literature, the coefficient of vegetation drag force was determined and the rationality of the numerical model was verified. The dissipative effects of vegetation with different distribution densities and heights were studied, and the attenuation amplitude of waves with different periods passing through vegetation areas on flat bottom and circular shoal terrains was discussed.The results show that when waves propagate through flat-bottom terrain areas covered by vegetation, energy dissipationcan becaused by vegetation. With the increase of vegetation distribution density, the wave energy dissipation effect of vegetation is gradually enhanced. The circular topography of the shoal leads to wave convergence behind the shoal, which can reduce the wave-absorbing effect of vegetation. Increasing vegetation density can reduce the influence of wave convergence effectively.æ›´å¤š è¿˜åŽŸ