浮筒

fú tǒng
  • buoy;bowl;float bowl
浮筒浮筒
浮筒[fú tǒng]
  1. 介绍水上飞机玻璃钢浮筒制备及工艺。

    The preparation and manufacture process of FRP float bowl of seaplane are introduced .

  2. 水上飞机玻璃钢浮筒的研制

    Development of FRP float bowl of seaplane

  3. 浮筒式深水钻井装置(ABS)的研制海上移动性钻探设备险

    Development of the artificial buoyant seabed ( ABS ) Marine Mobile Driling Unit Insurance

  4. 浮筒式滗水器在SBR工艺中的工作原理及设计

    Operation theory and design of displacer type water decanter in SBR technology

  5. 单浮筒贮油系统(SBS)模型的波浪试验

    Wave tests of a single buoy store system model

  6. 具体方法是通过悬链线理论和B样条拟合求得浮筒所受的锚链力,然后求解结构的时域运动方程得到结构物的运动响应和锚泊系统的内部应力。

    The mooring force on buoy is calculated in use of the catenary 's theory and B-Spline functions fitting , then the motion equation is solved in time domain .

  7. 由二维梁柱单元和集中质量法构建了立管和浮筒的数学模型,立管的运动方程用Wilsonθ法求解。

    Then , a 2-d beam-column element and the plumped mass method are introduced to form the model and dynamic equations of the riser and buoy , and Wilson - θ approach is used to solve these equations .

  8. FST-3000系列智能型扭力矩式浮筒液位计的应用与维护

    Application and Maintenance of FST-3000 Series Intelligent Float Level Gauge

  9. 由静态方法得到系泊力后,使用了四阶RungeKutta方法求解船舶的运动时历,并作为立管和浮筒动力计算的边界条件。

    With mooring forces derived from the static method , the four-order Runge-Kutta method is selected to solve the time history of the vessel , which can be used as the boundary conditions for dynamic calculation of the riser and buoy .

  10. 亚历山大·格雷厄姆·贝尔是发现家及航行术先驱。图为1930年月,他辅佐一个男孩在一架西科斯基S-38水陆两栖航行器的浮筒上保持平衡。

    Alexander Graham Bell , inventor and aviation pioneer , helps a boy balance on the pontoon of a Sikorsky S-38 amphibious aircraft in the1930s .

  11. 选用EJA系列智能型电动法兰式液位变送器代替原吹气式液位测量仪表及浮筒液位计,介绍电动法兰式液位变送器的特点;

    Through the application of more than 50 sets of EJA serials of intelligent electric flanged liquid level transducer at the company instead of original aerated liquid level instrumentation and float type liquid level instrumentation , a stable , reliable and easily maintainable performance is displayed .

  12. 对可装4300辆的汽车运输船(PCTC)带浮筒下水过程的动力学采用牛顿第二定律进行计算,对计算方法的选取以及影响计算结果的因素进行分析;

    The Newtonian second law is applied to calculate the hydrodynamic characteristics of the process of the 4 300 cars carrier launching with pontoon . This paper discusses about the computing methods and the factors influencing the numerical results .

  13. 沉船直线打捞法中浮筒充气方案计算机辅助设计研究

    A Research on Computer Assistant Design of Camel Charging for Salvage

  14. 水里的浮筒不会造成这种效果。

    A buoy in the water does not produce this effect .

  15. 船艇搬运机在打捞浮筒基地应用的构想

    Consideration on ship transporter in application of salvage of pontoons base

  16. 通过计算给出了气浮筒群结构的恢复力和恢复力矩的无量纲曲线。

    We drew the force curve of the structure after calculation .

  17. 浮筒液位变送器的工作原理及维修

    The Operational Principle and Maintain of the Float Type Level Transmitter

  18. 海军海洋气象自动观测发报浮筒海上自动气象观察站

    Navy oceanographic and meteorological automatic device marine automatic meteorological observing station

  19. 深海锚系圆形浮筒的动力分析

    Dynamic Analysis of Tension & Leg Single Buoy Mooring System

  20. 算例表明用这种方法来解决浮筒配置问题是可行的、有效的。

    The example shows the approach is feasible and effective .

  21. 基于粒子群算法的浮筒配置优化问题的研究

    Study on Optimization of Buoy-arranging Based On Particle Swarm Optimization

  22. 那船只用了二十分钟就到了浮筒处。

    It took the vessel only twenty minutes to reach the buoy .

  23. 多锚链系泊浮筒非线性漂移运动的时域模拟

    The nonlinear drift motion simulation of multi-chain mooring buoy in time domain

  24. 船里的男孩买了护城河里的浮筒。

    Boys in the boat bought buoys in the moat .

  25. 浮筒绑架援救破损舰船方案设计

    The scheme design for rescuing damaging ship by binding pontoons

  26. 液浮陀螺仪浮筒表面瞬态温度的确定

    Identification of transient temperature on the float surface of a floated gyroscope

  27. 大型船舶浮筒系泊断缆事故分析

    An Analysis on Broken Cable Accident of Large Ships Mooring at Buoy

  28. 19点30分从锚地移泊到13号码头/浮筒。

    30 shifting from anchorage to pier / buoy No.13 .

  29. 我们将用烟雾浮筒以吸引注意。

    We will use smoke buoys to attract attention .

  30. 高水位大型系船浮筒的设置与精度控制

    Placement of Large Mooring Buoy at High Water Stage and its Precision Control