随机波浪下遥控潜水器强非线性耦合空间运动与缆索安全性研究

模拟了带有脐带缆的潜水器(ROV)的强非线性流体动力学性能,由于ROV的前进速度与其它方向的运动速度为同一数量级,与传统的潜艇有重要的区别。潜艇中常用的按前进航速线性化处理的技术不能有效地用于潜水器,必须保留其运动方程中尽可能多的非线性项进行模拟。潜器本体的运动模型必须考虑为六自由度,脐带缆的运动必须考虑为三维运动。中继平台的运动幅值,可能会接近甚至超过水面船的运动幅值,这会增加ROV进出坞的困难。缆力对流速比对水面波浪更敏感、对垂向激励比水平激励更敏感。即使是随机波浪激励,深水吊索张力也会具有一定的周期性。近水面时这种周期性消失,两端张力趋于同步。     

深海无人遥控潜水器耐压电子舱结构设计与分析

研究深海无人遥控潜水器(ROV)耐压电子舱结构设计中涉及的力学分析技术。利用有限元数值分析方法校核耐压电子舱在深水条件下的强度、刚度与稳定性。根据深海耐压电子舱受力特点,优化其结构形式和尺寸,获得最优结构拓扑构型。对于耐压电子舱上下壳体接合面间接触问题,将非线性接触分析和简化分析法的计算结果进行比较。探讨加工误差与初始缺陷对耐压电子舱力学性能的影响。计算结果表明,耐压电子舱结构优选设计方案满足力学性能和重量要求,并且对加工误差与初始缺陷的影响不十分敏感。     

深海垂直吊放缆索系统固有频率和母船临界运动幅值快速计算方法

探索一种可描述缆索系统垂向吊放动力学行为的解析模型.给出它的自封闭方程、固有频率和简谐运动表达式,确定了母船和中际站之间的运动和张力传递函数,模拟结果能很好地符合实验估计值.导出沿着缆索的张力表达式,可用来预测缆索松驰和突变载荷的发生.     

浮基多体系统在波浪中展开的数值模拟

浮基多体系统在波浪中展开过程的顺序与快慢对系统的运动响应和连接处的力矩有较大影响。介绍了建立在齐次矩阵方法基础上的浮基多体系统时域运动求解,并对一具体浮基系统进行了建模和数值模拟,分析了上部机构以一定规律快速展开和慢速展开时系统的运动响应。结果表明,把齐次矩阵方法引入浮基多体系统的求解领域,其符号推导方便,运动学和动力学方程表达式变得相当简洁,而且编制程序也相对简便快捷。在相同波浪周期的情况下,多体系统的最大横摇角响应与波高正相关;在相同波高情况下,长周期的最大横摇响应要比短周期小;相对于波周期,波高对系统横摇响应的影响要大的多。     

全回转重吊船关键区域多体动力耦合优化设计

基于多学科交叉技术,本文提出了一种考虑运动和动力耦合的复杂多体系统优化设计分析方法.基于ADAMS(Automatic Dynamic Analysis of Mechanical Systems)平台建立全回转重吊船刚柔耦合虚拟样机,以AQWA(Advanced Quantitative Wave Analysis)...     

深海SPAR平台系泊系统耦合动力分析

随着海洋石油向深水领域的拓展,SPAR平台以其诸多优点逐渐成为海上油气生产的主流设施。主要研究SPAR与系泊系统间的耦合响应问题,在讨论了浮体在波浪中运动求解方法之后,阐述了如何利用非线性有限元技术对系泊缆索和立管进行动力分析和张力计算,以及浮体与系泊系统耦合计算的相关理论,对浮体和系泊系统耦合计算模型进行了描述。通过对某SPAR进行系泊系统耦合计算和对计算结果的讨论,证明了深海SPAR系泊系统耦合计算的正确性。     

深海采矿转场工况平台—水下系统耦合动力响应特性研究

针对水深6.0 km深海采矿装备,研究其转场工况平台—水下系统耦合动力响应特性。建立深海采矿平台—输浆管—中继站一体化耦合动力模型,其中采用有限元方法离散输浆管,采用势流理论计算平台水动力,基于Kalman滤波对动力定位系统进行参数整定,优化动力定位系统推力。考虑动力定位系统,计算水动力和采矿平台—输浆管—中继站的频域响应和平台—水下系统耦合时域运动响应,计算得到了平台时域运动响应、水下系统动力响应及动力定位系统推力响应。结果表明：建立的一体化耦合动力分析模型是可行的,可以有效预报平台及水下系统响应;转场0°浪向动力定位系统可以有效控制平台运动;中继站运动较小,输浆管轴力较大,建议将输浆管的浮力材料移动到流速较小的水下范围,可降低拖曳力,有利于输浆管的强度性能。     

深海声学释放器释放过程的动力学分析

深海释放器是海洋观测仪器、海洋工程中关键设备。研究考虑海流、释放器部件碰撞等因素的深海释放器释放过程的动力学情况,采用多体动力方法建立某深海释放机构的动力学模型,模拟释放机构的释放过程中各构件的运动情况和运动轨迹,计算释放机构在释放过程各组成构件的运动参数,该方法可以用于模拟深海释放器释放过程状况,分析释放器失效的原因和指导释放机构的设计。     

可着陆式水下机器人的多体动力学建模与仿真

可着陆式水下机器人由于变浮力机构的设计要求,其外形与结构较之传统的水下航行器更为复杂。在设计阶段对可着陆式水下机器人进行仿真和操纵性分析具有重要意义。文中采用多体系统动力学方法分析可着陆式水下机器人动力学特性,将作用在系统各组成部分上的流体动力、推进力以及其它作用力分别计算和考虑,建立了多体动力学模型,并进行了三维空间运动仿真。该方法为具有较复杂附体结构的水下机器人设计和动力学仿真提供了有效途径。     

拖曳系统拖曳动态过程仿真分析

对于海洋缆索系统,论文针对传统有限段法的不足,提出改进的缆索有限段法,缆索离散为若干弹性缆段组成的多柔体系统,根据缆索的特点选择适当的参考系和广义速率,引入有限元法中的形函数描述段内各点位移,根据Kane方程推导改进缆索有限段模型的运动方程。基于改进的缆索有限段法,提出了模拟拖曳缆索释放一回收过程的变拓扑结构模型,即用可变长度缆段长度的变化和缆段数量的改变建模缆索的释放和回收过程。文中对一海洋拖曳系统进行了动力学仿真,与海洋试验结果比较验证了模型的正确性。     

The motion of a deep-sea remotely operated vehicle system: Part 1: Motion observations

Rapid and high-resolution motion and tension measurements were made of a caged deep-sea remotely operated vehicle (ROV) system. Simultaneous measurements were made of all six components of motion at the cage and ship A-frame and of the tension in the tether at the ship. Data were collected for cage depths of 0–1765 m. The most significant forcing was in the wave-frequency band (0.1–0.25 Hz) and accounted for over 90% of the variance of vertical acceleration. The vertical acceleration of the cage lagged the acceleration of the A-frame by up to 1.9 s and its variance was larger by up to a factor 2.2. For moderate displacements of the A-frame (≤2 m), the system is only weakly non-linear because the harmonics (3rd and 5th) of the vertical acceleration of the cage account for less than 2% of the total variance. The system is essentially one-dimensional because only the vertical motion of the cage and the vertical motion of the A-frame were coherent, while horizontal motions of the cage were weak and incoherent with any component of motion of the A-frame. The natural frequency of the system is 0.22 Hz at 1730 m, and we estimate that it is within the waveband for depths between 1450 m and the full operating depth of 5000 m.Large vertical excursions of the A-frame produce momentary slack in the tether near the cage. Retensioning results in snap loads with vertical accelerations of 0.5 gravity. Large rates of change of tension and vertical acceleration first occur at the cage during its downward motion and propagate to the surface with the characteristic speed (3870 m s⁻¹) of tensile waves for the tether. Six echoes are clearly detectable at both ends of the tether, and their pattern is extremely repeatable in different snap loads. Due to misalignment of the tether termination with the centres of mass and buoyancy, the cage pitches by up 14° during a snap. The resulting small radius of curvature poses the greatest stress on the tether.     

On the motions of the underwater remotely operated vehicle with the umbilical cable effect

In this paper, a hydrodynamic model is developed to simulate the six degrees of freedom motions of the underwater remotely operated vehicle (ROV) including the umbilical cable effect. The corresponding hydrodynamic forces on the underwater vehicle are obtained by the planar motion mechanism test technique. With the relevant hydrodynamic coefficients, the 4th-order Runge–Kutta numerical method is then adopted to solve the equations of motions of the ROV and the configuration of the umbilical cable. The multi-step shooting method is also suggested to solve the two-end boundary-value problem on the umbilical cable with respect to a set of first-order ordinary differential equation system. All operation simulations for the ROV including forward moving, ascending, descending, sideward moving and turning motions can be analyzed, either with or without umbilical cable effect. The current effect is also taken into consideration. The present results reveal that the umbilical cable indeed significantly affects the motion of the ROV and should not be neglected in the simulation.     

Research on hydrodynamics model test for deepsea open-framed remotely operated vehicle

This paper presents the features of newly designed hydrodynamics test for the scaled model of 4500 m deepsea open-framed remotely operated vehicle(ROV),which is being researched and developed by Shanghai Jiao Tong University.Accurate hydrodynamics coefficients measurement and spatial modeling of ROV are significant for the maneuverability and control algorithm.The scaled model of ROV was constructed by 1:1.6.Hydrodynamics coefficients were measured through VPMM and LAHPMM towing test.And dynamics model was derived as a set of equations, describing nonlinear and coupled 5-DOF spatial motions.Rotation control motion was simulated to verify spatial model proposed.Research and application of hydrodynamics coefficients are expected to enable ROV to overcome uncertainty and disturbances of deepsea environment,and accomplish some more challengeable and practical missions.     

观察型水下机器人ROV系统配置研究

在简述无人遥控潜行器(ROV)系统构成的基础上,就观察型ROV的推进系统、成像系统、应用环境以及风险分析等方面进行深入探讨,提出了在我国海域环境下,有关水下机器人系统配置以及实际应用等方面的建议。     

堤坝检测水下机器人模糊自适应控制方法研究

GDROV是用于堤坝探测的水下机器人,设计上属于开架式机器人,其精确的数学模型很难获得.采用基于模糊逻辑的直接自适应控制方法,利用模糊基函数网络逼近理想控制输出,通过模糊逻辑动态调整控制器的参数自适应律,可有效解决水下机器人控制问题.建立GDROV的水动力模型,给出基于模糊逻辑的直接自适应控制算法,最后通过仿真试验和外场试验验证了该控制器对模型的不确定性具有较强的鲁棒性,且具有良好的跟踪性能.     

深海机器人视景仿真系统研究

以载人深潜器的各种水动力参数和实际尺寸为基础,根据几何空间坐标方程建立了其运动学模型,采用MultiGen公司的Creator建模工具和Vega视景环境完成了在深海虚拟环境下的系统仿真。该系统可以实现深海机器人的可视化,更加直观、生动和实时的反映其位姿状态和水面、水下巡航过程。该系统实际应用在中国科学技术馆深海机器人展馆项目上,一方面展示载人深潜器的水下工作过程,同时也使得观众有机会亲身体验潜水器的操纵与驾驶。实际运行结果表明,该系统逼真地演示了载人深潜器水面备航、无动力下潜以及近海底巡航等仿真过程,能够满足系统仿真的实时性要求。该系统还可以应用到深海环境模拟研究、水下机器人运动仿真、控制系统调试以及操纵驾驶训练等中。     

基于LES的ROV导管推进器梢隙流动数值研究

导管推进器是一种普遍应用于无人遥控潜水器（ROV）等潜器中的特种推进器。在桨叶与导管之间的梢隙中存在非常复杂的流动,本研究基于大涡模拟（LES）对导管推进器的梢隙流动进行了数值模拟分析。通过对时间步长的收敛性研究,建立两套基于不同网格类型的计算模型。将计算结果与试验进行对比,比较两种不同类型网格模拟结果的差异发现,切割体网格能够更好地捕捉到泄涡的细节,并结合梢隙流场的原理分析泄涡发展的过程,梢隙涡的驱动力是吸力面与压力面之间的压差。此外,随着进速系数增大,梢隙周向的涡管轴向分布范围减小,主泄涡发生位置延后,泄出涡的长度和数量都有所减少。     

自治水下机器人在深海采矿系统湖试中的应用

以大洋采矿前期的湖试为例,介绍了AUV在矿产资源调查和深海采矿中的应用。在深海采矿系统作业前期,利用AUV调查湖底的地形地貌、结核的分布与覆盖率,确定集矿机作业地点的大地坐标。在深海采矿系统作业后期,利用AUV调查集矿机在湖底的行走轨迹和压陷深度,估算回采率。     

Dynamics and control of a towed underwater vehicle system, part I: model development

Autonomous vehicles are being developed to replace the conventional, manned surface vehicles that tow mine hunting towed platforms. While a wide body of work exists that describes numerical models of towed systems, they usually include relatively simple models of the towed bodies and neglect the dynamics of the towing vehicle. For systems in which the mass of the towing vehicle is comparable to that of the towed vehicle, it becomes important to consider the dynamics of both vehicles. In this work, we describe the development of a numerical model that accurately captures the dynamics of these new mine hunting systems. We use a lumped mass approximation for the towcable and couple this model to non-linear numerical models of an autonomous surface vehicle and an actively controlled towfish. Within the dynamics models of the two vehicles, we include non-linear controllers to allow accurate maneuvering of the towed system.