考虑内流作用的钢悬链线立管动力特性分析

考虑内流的作用,研究钢悬链线立管动力特性。采用细长柔性杆模型,建立内流作用下钢悬链线立管运动方程,运用有限元法进行离散,通过求解动力特性方程得到立管的固有频率和模态,基于Matlab平台编写相应计算程序,探讨内流流速、顶张力和顶端压强对钢悬链线立管动力特性的影响。结果表明:随着内流流速的增加,立管的固有频率降低,高阶模态的反转点向立管底端移动;随着顶张力的增加,立管的固有频率增加,高阶模态的反转点向立管顶部移动;随着管内顶端压强的增加,立管的固有频率降低。     

考虑内流的海洋立管动力特性和动力响应的实验研究

本文考虑管内流体和管外流体的共同作用,对海洋立管进行试验研究。试验在中国海洋大学物理海洋试验室进行,通过试验得到了立管的一些有价值的规律:随着外流流速逐渐增大,立管的一阶激振频率也逐渐增大,在一定的外流速下,会激起立管的二阶激振频率甚至于三阶激振频率,由于立管的刚度较大,内流对立管的影响并不明显。但是当外流达到一定流速,这种影响就会显现出来,内流的存在会降低海洋立管的振动频率。     

海洋输流立管耦合动力分析

综合考虑黏性内流以及立管轴向和流向的耦合效应等多种因素对立管动力响应的影响,基于Hamilton原理推导得出海洋立管耦合振动方程,采用Galerkin法进行数值求解。首先分析波流载荷与平台运动联合激励和仅在平台运动作用下立管动力响应的差异,然后讨论黏性内流和顶部张力对立管动力特性和响应峰值的影响。计算结果表明:波流与平台运动耦合作用和仅在平台运动作用下的立管各阶振动模态和振动峰值存在明显差异,波浪和海流对立管的直接作用不可忽略;内流运动黏性会改变立管振型峰值,立管流向一阶固有频率随内流流速增大而减小,流向和垂向振动峰值分别随之增加和减小,但这种影响很有限,且可以通过增大立管顶部预张力来抵消。     

海洋环境荷载下输液立管的静、动力特性研究

考虑管内流动流体和管外海洋环境荷载共同作用 ,建立海洋立管侧向运动微分方程。用Hermite插值函数离散 ,在微机上编写海洋立管静、动力分析程序 ,通过计算分析研究管内流体对立管侧向变形和应力的作用 ;另外 ,探讨管内流体的流动速度和立管顶端的预张力对立管动力特性的影响。结果表明 ,立管变形和应力均随管内流体流动速度增加而增大 ,同时内流速度的增大会降低立管的固有频率 ,但适当增大立管顶端预张力会抵消内流流速增加引起的固有频率下降。     

顶部浮体激励下钢悬链线立管的动力响应分析

考虑钢悬链线立管大变形的特性以及内流的影响,利用Kane方法和拉格朗日应变理论建立钢悬链线立管的二维动力学模型。将顶部浮体的激励简化为一个沿顺流向的周期作用力施加于立管顶部,采用平均加速度法求解立管的动力响应。探讨顶部浮体不同激励频率下立管的非线性动力响应以及内流流速的大小对管道共振响应幅值的影响。     

考虑阻尼海底悬跨段管道的动力特性及允许悬空长度

以海底悬跨段输液管道为研究对象,考虑管道结构阻尼、流体附加阻尼、管内流体流动及管道轴向力和压强的作用,对其进行受力分析,导出管道振动微分方程,进而得到管道动力特性方程。用Hermit插值函数对管道的动力特性方程进行离散得到有限元表达式,采用复模态分析法,求得管道的自振频率。为防止管道发生横向涡激振动,用约化速度作为控制条件,确定管道允许悬空长度。结果表明,管道允许悬空长度随着内流流速、轴向压力和管内压强的增加而减小,随着轴向拉力的增加而加大。     

关于海洋立管设计标准中内流作用的分析与探讨

针对内流对海洋立管动力特性的影响,比较国外现行的两部海洋立管设计标准(美国API RP 2RD和挪威DNV-OS-F201)中对内流的描述和相关规定。从立管的动力平衡方程入手,结合已有的关于稳定内流的理论和试验研究成果,通过计算比较,指出两个标准中尚需改进之处,并提出相应的建议。     

驳船横荡运动下海洋立管的动力响应

海洋浮式生产系统下立管的受力情况复杂,国内的研究大多集中于两端固支或简支的情况。本文则以水面驳船的横荡运动作为立管上端的动力边界条件,将Matteo Luca Facchinetti的尾流振子模型与考虑外流涡激振动作用下海洋立管运动微分方程相结合,得到管道与流体的耦合振动方程,用Hermit插值函数将方程进行有限元离散,并用Newmark时程分析法及迭代法求解,得到管道各点的位移时程曲线。结果表明:立管的振动频率主要由上端驳船的运动频率所确定,随着驳船运动频率的增加,立管中点的位移幅值先增加后减小;在有动边界存在的条件下,改变外流流速对立管中点的位移幅值影响不大。     

考虑温度应力下深海输油立管动力特性及响应研究

考虑深海输油立管管内外温差产生的温度应力以及管内流体流动和管外海洋环境荷载的共同作用,建立了深海输油立管振动微分方程,采用有限元法对输油立管动力特性及动力响应进行求解,并将考虑温度应力及不考虑温度应力的立管动力特性及在波浪作用下的立管动力响应进行了对比。结果表明,对于动力特性,温度应力的存在会使得立管自振频率降低;对于动力响应,会使得波浪作用下动力响应幅值增强而频率略有降低,易引起立管的疲劳破坏。     

海洋立管涡激振动模型的实验验证

考虑内流作用利用功能原理建立顶张力立管涡激振动响应数值模型,采用尾流振子模型模拟涡激振动升力,利用Hermit插值函数将其离散得到立管振动响应的矩阵方程形式,运用Newmark-β法在时域内迭代求解其动力响应。在山东省海洋工程重点实验室进行了阶段流作用下的大长细比海洋立管涡激振动试验,对比数值模拟和试验结果表明该模型对于考虑内流作用的大长细比海洋立管涡激振动响应预报是有效的,为深水立管涡激振动研究提供一定的借鉴。     

Dynamic Characteristics of Marine Risers Conveying Fluid

The lateral vibration differential equation for a marine riser conveying fluid is derived by useof the small deflection theory.and the effect of internal flow velocity and top tension on the natural fre-quency of the riser is studied by use of FEM.At the same time,the preliminary relationship between thenatural frequency and riser span under different internal flow velocities is obtained,the effect of riser sup-ports on the vibration frequency is computed.It is found that the natural frequency of the marine riser in-creases with the increase of top tension.however decreases with the increase of internal flow velocity.In ad-dition,the frequency decreases drastically with the increase of riser span.     

水下输液管道动力特性研究

该文研究水下横向输液管道的动力特性 ,假定管道系统承受外界均匀流的作用 ,同时考虑管内流体流动的影响 ,建立了水下输液管道侧向振动的微分方程。采用 Hermite插值函数和Galerkin法离散得到其有限元标准形式。研究管内流动为恒定流时输液管道长度、内部流体流动速度对管道动力特性的影响及管内流动含有谐波挠动的情况下输液管道固有频率的变化。结果表明 ,在管内恒定流动的情况下 ,输液的自振频率随管道长度及管内流速的增加而降低 ,同时管内流动的谐波挠动对管道的自振频率也有影响。     

深海悬垂取水管振动特性研究

深海悬垂取水管的设计趋向于大直径、高内流流速,内流对取水管振动特性的影响不可忽略,分析内部流动引起的管道动态失稳行为以及评估失稳临界流速具有重要工程意义。基于小尺度模型试验,研究内流对深海悬垂取水管道振动特性的影响规律,结果表明：随着内流流速增加,取水管模型会发生动态失稳行为,表现为一种间歇性的近周期运动,该运动主要由管道一阶弯曲模态引起的不稳定性诱导。管道材料、顶端连接方式及底部配重块均影响其动态稳定性,顶端固定连接时质量比小的管道更易发生动态失稳;顶端变为铰接时,质量比大的管道失稳临界流速变小,质量比小的管道失稳临界流速变大。相比顶端边界条件,底部配重块对管道失稳临界流速影响不显著但可以减小其振动幅值。     

Simplified Prediction Model for Vortex-Induced Vibrations of Top Tensioned Risers

According to the characteristics of deepwater top tensioned risers, a simplified model is presented to predict the multi-modal response of vortex-induced vibration （VIV） in non-uniform flow based on energy equilibrium theory and the exporimental data from VIV self-excited and forced oscillations of rigid cylinders. The response amplitude of each mode is determined by a balance between the energy fed into the riser over the lock-in regions and the energy dissipated by the fluid damping over the remainders. Compared with the previous prediction models, this method can take fully account of the intrinsic nature of VIV for low mass ratio structures on lock-in regions, added mass and nonlinear fluid damping effect, etc. Moreover, it is the first time to propose the accurate calculating procedure for VIV amplitude correction factor by solving energy equilibrium equation and a closed form solution is presented for the case of a riser of uniform mass and cross-section oscillating in a uniform flow. The predicted values show a reasonable agreement with VIV experiments of riser models in stepped and sheared currents.     

Effect of upward internal flow on dynamics of riser model subject to shear current

Numerical study about vortex-induced vibration(VIV) related to a flexible riser model in consideration of internal flow progressing inside has been performed.The main objective of this work is to investigate the coupled fluid-structure interaction(FSI) taking place between tensioned riser model,external shear current and upward-progressing internal flow(from ocean bottom to surface).A CAE technology behind the current research which combines structural software with the CFD technology has been proposed.According to the result from dynamic analysis,it has been found that the existence of upward-progressing internal flow does play an important role in determining the vibration mode(/dominant frequency),vibration intensity and the magnitude of instantaneous vibration amplitude,when the velocity ratio of internal flow against external current is relatively high.As a rule,the larger the velocity of internal flow is,the more it contributes to the dynamic vibration response of the flexible riser model.In addition,multi-modal vibration phenomenon has been widely observed,for asymmetric curvature along the riser span emerges in the case of external shear current being imposed.     

Analysis of Dynamic Characteristics of Submarine Free Spanning Pipelines by Complex Damping Method

Considering the effect of the internal flowing fluid and the external marine environmental condition, the differential equation for the vortex-induced vibration (V1V) of the free spanning pipeline is derived and is discretized by the Hermit interpolation function. The free vibration equation with the damping term is solved by the complex damping method for the natural frequency, and then the effect of fluid damping on the natural frequency of the free spanning pipeline is analyzed.The results show that fluid damping has a significant influence on the damped natural frequency of the free spanning pipeline in the lock-in state, while it has little influence when the pipeline is out of the lock-in state. In the meantime,the change of the free span length has the same effect on the damped natural frequency and the undamped natural frequency.     

弯曲柔性立管举升气液两相流时的流固耦合效应研究

海洋油气混输时,气液两相流与混输立管之间的双向流固耦合作用机理十分复杂.针对柔性立管与气液两相流的流固耦合响应问题,在气液两相循环试验装置中开展了不同流型两相流流动特性及柔性立管振动响应的测试,利用高速摄像非介入测试技术同步捕捉了柔性立管的振动位移与管内的流型演变过程,对比了不同流型气液两相流诱导的立管振动响应特性,通过对比固定和振动立管内的气液两相流动特性,辨析了振动对管内两相流动的影响.结果表明:柔性立管中出现了泡状流、泡状—段塞流、段塞流、段塞—搅拌流和搅拌流五种流型,不同流型的气液两相流诱导立管振动的机理不同,在段塞—搅拌流作用时立管的振动响应最剧烈.与固定立管相比,强烈的振动不同程度地改变了气液两相流的流动特性,振动立管中部分两相流流型转变的临界条件有明显地调整,相对而言,振动对搅拌流和泡状流的影响较小.     

Dynamic and static analysis of a marine riser

A frequency domain normal mode solution is presented for the dynamic response of an unbuoyed marine riser subjected to periodic excitation from a surface vessel in the direction of wave propagation. The variable tension beam-column equation is solved in terms of normal modes of free vibration of the riser and the rigid body displacement. Drag forces on the riser are represented by Morison's formula taking account of the velocity of the riser and wave-induced fluid velocity. A periodic solution for the flexural motion of the riser and the bending stress is then obtained by means of an iterative solution of the frequency response function. The drag force induced stresses arising from a linearly varying current are also determined. The results presented compare favourably with those obtained by other methods.