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41.
气水比对移动床生物滤器净化海水养殖废水的影响 总被引:1,自引:0,他引:1
生物滤器是海水养殖废水净化的核心处理单元,而气水比是影响移动床生物滤器处理效率的关键因素。本实验采用挂膜成熟的移动床生物滤器和人工模拟海水养殖废水,研究了不同气水比(6︰1、10︰1、15︰1、20︰1、30︰1)对移动床生物滤器处理海水养殖废水效能的影响。结果表明:随着气水比的增大,氨态氮(TAN)去除率呈现出先降低后增加的趋势,亚硝酸盐(NO_2~–-N)的积累率呈现出先增加后降低的趋势,化学需氧量(COD)去除率呈现降低的趋势。气水比为6︰1时TAN和COD平均去除率最大(TAN 12.55%±0.80%,COD 16.63%±1.28%),NO_2~–-N平均积累率相对较小(109.71%±23.94%),且出水水质稳定,波动最小,对水质的净化效果明显好于其他的气水比条件,因此气水比6︰1是实验条件下的最佳气水比,可为实际生产应用提供理论参考。 相似文献
42.
养殖废水的综合利用与无公害化处理排放是实现水产养殖业健康可持续发展的重要保障。作者采用太平洋牡蛎(Crassostrea gigas)及龙须菜(Gracilaria lemaneiformis)混养和单养的方式处理大西洋鲑工业化循环水养殖系统排放的废水,设置贝类组、藻类组、贝藻组3组处理,探讨了贝藻混养方式和贝类、藻类单养对废水中主要水质因子(N、P营养盐、化学需氧量(COD)和总悬浮颗粒物(TSS))的处理效率,实验周期为30 d。结果表明,牡蛎和龙须菜混养的方式处理养殖废水效果较好,其对氮、磷营养盐、COD及TSS的去除效率分别为:总氨态氮41.67%±8.82%、硝酸盐氮33.96%±0.34%、总磷7.18%±0.03%、COD 78.87%±1.82%和TSS 70.50%±1.65%,而亚硝酸盐氮出现一定的积累。综合分析,牡蛎和龙须菜混养的方式处理养殖废水的效率优于牡蛎和龙须菜的单独处理。 相似文献
43.
文中选取MGEX跟踪站部分测站的2016年2月1日1天的观测数据,在截止高度角分别为5°、15°、25°、30°、40°、45°的情况下,分析BDS(C)、GPS(G)、GPS+BDS(GC)、BDS+GALILEO(CE)、GPS+GALILEO(GE)、GPS+BDS+GALILEO(GCE)六种组合模式的单点定位(SPP)的定位性能. 研究结果表明:GPS+BDS+GALILEO(GCE)组合稳定性最好. 同一高度截止角下,卫星数目最多,历元可用率最高,为96%,相比其他模式,定位精度提高了20%~40%. 在建筑物密集区、山区、树林和遮挡严重的区域具有很好的应用价值. 相似文献
44.
土壤厚度是农业生产、国土空间规划和生态保护修复等工作重要的基础信息.为探索低山丘陵区土壤厚度空间分布快速评定的有效方法,本研究对在河南省罗山县实测的593个土壤厚度数据进行了数理统计,总结了低山丘陵区土壤厚度密切相关的五种环境影响因子:坡度、土地利用类型、建造构造、海拔和植被覆盖率,并运用主成分分析法确定了上述影响因子对土壤厚度的影响权重为:0.151、0.303、0.263、0.184、0.100.最后进行了土壤厚度预测性制图,并通过野外实测土壤厚度数据进行了精度验证,结果显示该方法验证精度为72%,卡帕系数为0.672.该研究为低山丘陵区土壤厚度制图提供了一种快速高效精准的方法,为国土空间规划和生态保护修复提供技术支撑. 相似文献
45.
介绍了“十五”地电阻率观测运行实时监控、数据超差报警、数据常规处理的原理和方法,以及软件的主要功能、应用范围、运行环境、推广使用前景等。 相似文献
46.
潮区界是标志水位是否受潮动力影响的关键界面,对港航安全与区域防洪意义重大.限于研究方法,近期海平面上升以及大规模工程建设运行背景下的潮区界变动情况亟待研究.对2007~2016年长江下游水文站实测水位资料进行频谱分析,结合红噪声检验判断水位过程中的潮差变化,分析了长江河口潮区界变动范围与特征.结果显示:(1)特大枯水时期,九江站流量约8440m3s-1时,潮区界在九江附近;特大洪水时期,九江站流量约66700m3s-1时,潮区界在枞阳闸与池口之间;(2)自上而下九江流量对潮区界的影响沿程减弱,南京潮差的影响沿程增强,相近流量/潮差下潮区界位置有变动,变动范围随流量的增大而增大,随潮差的减小而增大;(3)在海平面上升以及流域河口工程建设的持续影响下,未来潮区界或将进一步上移. 相似文献
47.
SV波入射情况下V型河谷地形对地震动的影响分析 总被引:2,自引:0,他引:2
基于局部人工边界的显式有限元方法,给出了二维V型河谷地形在SV波垂直人射下地面运动数值解,并分析其地震动分布规律以及两侧不同的边坡角度对于地震动分布规律的影响.数值结果表明:谷底的角点、两岸靠近河谷的点、两侧谷坡靠近谷底的点以及靠近两岸的点,对地表位移有放大作用,而对其邻近区域地表位移有抑制作用.这是由于角点处存在面的... 相似文献
48.
李德香,省地勘局局长,全国省级地勘局长中惟一的女性。她待人温和厚重,宽容中又不失坚毅果敢,是一位很有亲和力的领导。2月17日,省地勘局地勘工作会议结束后,我们就矿业权这一话题采访了她。 相似文献
49.
刘显通 阮征 胡胜 万齐林 刘黎平 罗亚丽 胡志群 黎慧琦 肖辉 雷卫延 夏丰 饶晓娜 冯璐 赖睿泽 吴翀 叶朗明 郭泽勇 张羽 王瑶 颜朝潮 袁锦涵 《热带气象学报(英文版)》2023,29(1):1-15
Aiming at the needs of mechanism analysis of rainstorms and development of numerical prediction models in south China, the Guangzhou Institute of Tropical and Marine Meteorology of China Meteorological Administration and the Chinese Academy of Meteorological Sciences jointly set up the Longmen Cloud Physics Field Experiment Base,China Meteorological Administration. This paper introduces the instruments and field experiments of this base, provides an overview of the recent advances in retrieval a... 相似文献
50.
In this paper, the data of Automatic Weather Stations (AWSs), ERA5 reanalysis, sounding, wind profile radar, and dual-polarization radar are used to study an extreme rainfall event in the south China Coast on 11 to 12 May 2022 from the aspects of thermodynamics and microphysical characteristics under the influence of low-level jets (LLJs). Results show that: (1) The extreme rainfall event can be divided into two stages: the first stage (S1) from 0000 to 0600 LST on May 12 and the second stage (S2) from 0700 to 1700 LST on the same day. During S1, the rainfall is mainly caused by the upper-level shortwave trough and the boundary layer jet (BLJ), characterized by strong upward motion on the windward side of mountains. In S2, the combined influence of the BLJ and synoptic-system-related low-level jet (SLLJ) increases the vertical wind shear and vertical vorticity, strengthening the rainstorm. In combination with the effect of topography, a warm and humid southwest flow continuously transports water vapor to farther north, resulting in a significant increase in rainfall over the study area (on the terrain’s windward slope). From S1 to S2, the altitude of a divergence center in the upper air decreases obviously. (2) The rainfalls in the two stages are both associated with the mesoscale convergence line (MCL) on the surface, and the wind field from the mesoscale outflow boundary (MOB) in S1 is in the same direction as the environmental winds. Due to a small area of convergence that is left behind the MOB, convection moves eastward quickly and causes a short duration of heavy rainfall. In S2, the convergence along the MOB is enhanced, which strengthens the rainfall and leads to strong outflows, further enhancing the surface convergence near the MOB and forming a positive feedback mechanism. It results in a slow motion of convection and a long duration of heavy rainfall. (3) In terms of microphysics, the center of a strong echo in S1 is higher than in S2. The warm-rain process of the oceanic type characterizes both stages, but the convective intensity in S2 is significantly stronger than that in S1, featuring bigger drop sizes and lower concentrations. It is mainly due to the strengthening of LLJs, which makes small cloud droplets lift to melting levels, enhancing the ice phase process (riming process), producing large amounts of graupel particles and enhancing the melting and collision processes as they fall, resulting in the increase of liquid water content (LWC) and the formation of large raindrops near the surface. 相似文献