基于水动力-饵料示踪耦合模型的浮筏式贻贝养殖区布局优化OA
Layout optimization of suspended mussel farms based on a coupled hydrodynamic-seston tracer model
为了解决枸杞岛浮筏式贻贝养殖区因布局不合理导致水交换能力下降、局部饵料供给不足进而严重影响贻贝生长的问题,基于三维水动力模型FVCOM,耦合示踪剂模块和质点追踪模块,系统评估优化方案对养殖区水交换能力、饵料外源补给及贻贝肥满度的影响.结果显示,现行养殖布局下,近岸及养殖区中心小潮期间周期性出现饵料耗竭现象,最长水体交换时间超过30 h.清退近岸养殖单元、增设喇叭形航道与筏架走向优化等单因素优化在养殖面积分别减少7.1%、9.6%、0的前提下,小潮期间饵料低值区面积分别较现状减少约30.3%、48.4%和11.3%,显著改善了局部饵料短缺.综合优化方案并协同上述3种单因素方案,养殖面积较现行养殖布局缩减13.7%,但小潮期间饵料低值区面积可减少70%,最长水体交换时间缩短至低于20 h,可显著提升养殖区整体饵料浓度及贻贝日均生长量,贻贝个体平均可摄入饵料量增加后,养殖区全域贻贝肥满度可提升6.0%.研究表明,综合优化方案可有效改善养殖区水交换和饵料补给,降低养殖海域各分区内贻贝生长的空间差异,可为浮筏式贻贝养殖区的科学管理提供参考依据.
To address the issues of deteriorated water exchange capacity and localized seston depletion in the suspended raft mussel farming area of Gouqi Island caused by suboptimal layout design,which severely impacts mussel growth,this study employed the three-dimensional hydrodynamic model FVCOM coupled with a tracer module and a particle-tracking module to systematically evaluate optimization schemes for their effects on water exchange capacity,exogenous seston supply,and mussel condition index.The results revealed that under the current farming layout,periodic seston depletion occurs during neap tides in nearshore areas and the central farming zone,with the maximum water exchange time exceeding 30 hours.Single-factor optimizations,including removal of nearshore farming units,addition of trumpet-shaped channels,and optimization of raft orientation,reduced the area of low-seston zones during neap tides by approximately 30.3%,48.4%,and 11.3%respectively while decreasing the farming area by 7.1%,9.6%,and 0 compared to the current layout,significantly mitigating localized seston shortages.The comprehensive optimization scheme integrating all three single-factor measures reduced the total farming area by 13.7%compared to the current layout while achieving a 70%reduction in low-seston zones during neap tides and shortening the maximum water exchange time to less than 20 hours.This significantly enhanced the overall seston concentration and daily growth rate of mussels in the farming area.With increased average seston intake per mussel,the condition index across the entire farming area improved by 6.0%.The study demonstrates that the comprehensive optimization scheme effectively improves water exchange and seston replenishment in the farming area while reducing spatial disparities in mussel growth among different zones.This research provides scientific reference for the management of suspended raft mussel farming areas.
白雪岩;钟威;李艳姣;林军
上海海洋大学 海洋科学与生态环境学院,上海 201306上海海洋大学 海洋科学与生态环境学院,上海 201306上海海洋大学 海洋科学与生态环境学院,上海 201306上海海洋大学 海洋科学与生态环境学院,上海 201306||上海海洋大学 海洋牧场工程技术研究中心,上海 201306||自然资源部海洋生态监测与修复技术重点实验室,上海 200137
农业科技
浮筏式贻贝养殖布局优化示踪剂衰减模型质点追踪枸杞岛
suspended mussel farminglayout optimizationtracer decay modelparticle trackingGouqi Island
《上海海洋大学学报》 2026 (3)
752-766,15
国家自然科学基金(42376207)
评论