用于池塘养殖尾水处理的串联式旋流器水动力特性及分离效率

为了将多级旋流分离技术应用于池塘养殖尾水处理,并解决旋流器的水力停留时间短、分离效率低等问题,根据池塘养殖南美白对虾的尾水特点,结合工业标准150旋流分离器的结构参数,设计了一种串联式旋流分离器。该研究基于欧拉-拉格朗日方法,结合雷诺应力湍流模型与离散相模型,建立了串联式旋流分离器的三维两相内流场数值计算模型。在对比试验数据验证计算方法有效性和流场网格独立性的基础上,分析了进水口流量、锥角、颗粒粒径和密度等参数对旋流器的流场特征和分离效率的影响机制,并提出了多级\     

中国水产健康养殖的关键技术研究

健康养殖包括养殖设施、苗种培育、放养密度、水质处理、饵料质量、药物使用、养殖管理等诸多方面,采用合理的、科学的、先进的养殖手段,从而获得质量好、产量高的产品及环境均无污染,使经济、社会、生态产生综合效益,并能保持稳定、可持续发展。今后工作重点应是：(1)优化养殖条件,保护生态环境。(2)加强病害综合防治措施,规范渔用药物使用。(3)开展抗病、抗逆养殖新品种的选育。(4)开发优质高效饲料与合理使用饲料并举。(5)加快研究和推广健康养殖技术,提高经济和生态效益。(6)加快制定健康养殖标准,加强质量监督检测体系建设(不属健康养殖技术的范畴)。     

铬在渔业中应用的研究进展

综述了铬在渔业中应用的研究进展,包括铬作为水产养殖饲料添加剂,对水生生物生长、毒性和生理活性的影响,及铬对养殖水体的污染、对渔业生物的危害以及检测方法等等,并提出了今后的研究展望。     

Comparative economic performance and carbon footprint of two farming models for producing Atlantic salmon (Salmo salar): Land-based closed containment system in freshwater and open net pen in seawater

Ocean net pen production of Atlantic salmon is approaching 2 million metric tons (MT) annually and has proven to be cost- and energy-efficient. Recently, with technology improvements, freshwater aquaculture of Atlantic salmon from eggs to harvestable size of 4–5 kg in land-based closed containment (LBCC) water recirculating aquaculture systems (RAS) has been demonstrated as a viable production technology. Land-based, closed containment water recirculating aquaculture systems technology offers the ability to fully control the rearing environment and provides flexibility in locating a production facility close to the market and on sites where cost of land and power are competitive. This flexibility offers distinct advantages over Atlantic salmon produced in open net pen systems, which is dependent on access to suitable coastal waters and a relatively long transport distance to supply the US market. Consequently, in this paper we present an analysis of the investment needed, the production cost, the profitability and the carbon footprint of producing 3300 MT of head-on gutted (HOG) Atlantic salmon from eggs to US market (wholesale) using two different production systems—LBCC-RAS technology and open net pen (ONP) technology using enterprise budget analysis and carbon footprint with the LCA method. In our analysis we compare the traditional open net pen production system in Norway and a model freshwater LBCC-RAS facility in the US. The model ONP is small compared to the most ONP systems in Norway, but the LBCC-RAS is large compared to any existing LBCC-RAS for Atlantic salmon. The results need to be interpreted with this in mind. Results of the financial analysis indicate that the total production costs for two systems are relatively similar, with LBCC-RAS only 10% higher than the ONP system on a head-on gutted basis (5.60 US$/kg versus 5.08 US$/kg, respectively). Without interest and depreciation, the two production systems have an almost equal operating cost (4.30 US$/kg for ONP versus 4.37 US$/kg for LBCC-RAS). Capital costs of the two systems are not similar for the same 3300 MT of head-on gutted salmon. The capital cost of the LBCC-RAS model system is approximately 54,000,000 US$ and the capital cost of the ONP system is approximately 30,000,000 US$, a difference of 80%. However, the LBCC-RAS model system selling salmon at a 30% price premium is comparatively as profitable as the ONP model system (profit margin of 18% versus 24%, respectively), even though its 15-year net present value is negative and its return on investment is lower than ONP system (9% versus 18%, respectively). The results of the carbon footprint analysis confirmed that production of feed is the dominating climate aspect for both production methods, but also showed that energy source and transport methods are important. It was shown that fresh salmon produced in LBCC-RAS systems close to a US market that use an average US electricity mix have a much lower carbon footprint than fresh salmon produced in Norway in ONP systems shipped to the same market by airfreight, 7.41 versus 15.22 kg CO₂eq/kg salmon HOG, respectively. When comparing the carbon footprint of production-only, the LBCC-RAS-produced salmon has a carbon footprint that is double that of the ONP-produced salmon, 7.01 versus 3.39 kg CO₂eq/kg salmon live-weight, respectively.     

竹炭对养殖水净化效果研究

选取不同竹种、不同竹龄、不同炭化终点温度和不同炭化时间的竹炭,对鱼塘养殖水进行吸附净化处理,通过测试水的浊度、COD和氨氮去除率等指标研究竹炭对养殖水的净化效果.结果表明:用竹炭吸附后的水样的浊度、COD和氨氮等水质指标都有明显改善;毛竹炭对水质净化处理效果最理想,氨氮去除率达到90％以上;随着竹龄的增大,竹炭的净化处理效果增强,6年生的毛竹炭用于水质净化较适宜;不同炭化温度的竹炭对水质净化有选择性;炭化时间越长竹炭对鱼塘养殖水的吸附净化效果越好.     

贻贝浮筏养殖设施水动力效应及附生海藻碎屑输运的数值模拟

基于三维海洋数值模式(estuarine coastal ocean model, semi-implicit, Ecom-si)对枸杞岛邻近贻贝养殖海域的水动力进行了数值模拟研究。通过在模型动量方程中添加动量损耗项,实现了对贻贝浮筏养殖设施阻流效应的模拟,采用实测数据对模型进行了潮位及流速的验证。利用验证良好的数值模型模拟了潮流驱动下养殖设施附生海藻碎屑漂移及沉降。结果表明,贻贝养殖设施及养殖贝串在海表的阻流效应使表层流速降低了约80%,中、下层流速分别降低了约50%和30%,在养殖海域外围因过流面的减小使得养殖场外围的流速有所增大。应用拉格朗日质点追踪模块模拟的结果表明,当碎屑质点处于悬浮状态即质点沉降速率(w)为0 m/s时,质点需要约600 h才能达到36.79%(e^-1)的沉底率;且无阻流效应时,沉底质点的分布在距养殖区中心9.0～10.5 km的区域内,有阻流效应时,质点的沉底范围分布在距养殖区中心7.5～8.5 km的区域内。当w大于0 m/s时,3种碎屑沉降速度的结果差异不大,大约在80 h内质点的沉底率达到99%,无阻流效应时质点沉降区域为距养殖...     

半封闭循环水养殖系统中高体革鯻养殖密度研究

在半循环水养殖系统中研究了养殖密度对体重为50～100 g的高体革鯻苗种的影响。试验设置3个密度组:低密度组100尾/m3(5 kg/m3)、中密度组260尾/m3(13 kg/m3)和高密度组360尾/m3(18 kg/m3)。研究表明:各密度组中试验鱼的生长表现出了明显的差异,生长效率、特定生长率和日增重随着养殖密度的升高而明显降低;大小变动系数和饵料系数随着养殖密度的升高而明显增加。对试验鱼的生理指标分析表明,试验初期,密度对试验鱼血清中的皮质醇、补体C3、谷草转氨酶(ALT)和谷丙转氨酶(AST)有显著影响;试验结束时,3个密度组试验鱼血清中的皮质醇、谷草转氨酶和谷丙转氨酶没有明显差异。综合对检测指标的结果分析,认为本试验条件下,体重50～100 g的高体革鯻幼鱼的比较适宜的养殖密度是260尾/m3。研究亮点:(1)高体革鯻是近年来逐渐引起关注的优良淡水养殖品种,比较适合高密度集约化养殖,但关于其适宜养殖密度的研究尚未见报道。研究高体革鯻幼鱼的适宜养殖密度,希望为生产提供理论基础。(2)不仅分析了常规的生长指标和生理指标,将部分生产指标一并纳入分析,作为评价养殖密度适宜性的标准。     

四种填料滤器处理养鱼废水的硝化性能

为了研究不同填料对海水养殖废水处理的硝化效能,并为生物滤器硝化动力学模型的构建、生物滤器的设计与管理提供基础数据支持,本文在5个化学耗氧量/总氨氮比0、0.8、2、6、12条件下,研究了竹制空心生化球、麦饭石、陶粒和生物滤球等4种填料的生物滤器去除模拟海水养殖废水中化学需氧量和总氨氮,以及生物膜微生物种群结构和数量的变化。结果表明：在低化学需氧量/总氨氮（＜6）条件下麦饭石填料的生物滤器具有最高的化学需氧量和总氨氮去除效能,最高分别可达850和21 g/(m3·d)（化学需氧量/总氨氮=0.8）;竹制空心     

基于GF-3全极化SAR影像多特征优选的水产养殖塘提取

高分三号作为中国首颗民用高分辨率多极化合成孔径雷达卫星,为水产养殖用地监测提供了重要的数据源.为了充分利用GF-3全极化SAR影像,该研究提出了一种基于特征优选的全极化SAR影像养殖塘提取方法.首先通过极化分解和灰度共生矩阵方法共获取了55维特征;然后对影像进行多尺度分割,并利用随机森林-递归特征消除(Random F...     

生物浮床技术在水产养殖中的应用概况

生物浮床技术作为生物操纵方法的一种,是一种原位生态修复技术,它是利用浮床植物根系或者茎叶吸收、富集、降解或固定受污染水体中的(有机)污染物,通过对植物的收割(收获)以实现降低或者消除水体污染物,达到净化水质、修复环境的目的.综述了生物浮床技术的原理与特点及生物浮床的应用效果,并结合生物浮床的技术特点探讨其在水产养殖应用中存在的问题,最后对生物浮床技术在水产养殖中的应用前景进行了展望.